JP2015100681A - Magnetic resonance imaging apparatus and program for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a magnetic resonance imaging apparatus having a function for reordering images in order registered in an imaging plan and sending the images when unexpected replacement of imaging order has occurred.SOLUTION: The magnetic resonance imaging apparatus includes: an imaging plan storage part 51 in which a plurality of imaging plans composed of a plurality of imaging units are stored; an imaging management part 21 which selects an appropriate imaging plan from the plurality of imaging plans on the basis of a test request on a subject, performs imaging for every imaging unit composing the selected imaging plan and manages at least one of safety and quality in the imaging; an imaging part 8 which acquires an image for every imaging unit composing the selected imaging plan; an imaging order change part 25 which changes imaging order in the selected imaging plan in accordance with the management of at least one of the safety and quality in the imaging; and an acquisition image order change part 27 which reorders the images acquired by the imaging part 8 on the basis of the selected imaging plan.

Description

  Embodiments as one aspect of the present invention relate to a magnetic resonance imaging apparatus and a program thereof.

  The acquisition of medical images by a medical imaging device (hereinafter referred to as a modality device) used in the medical field is indispensable in modern medical care because it enables diagnosis by looking at the inside of the body without damaging the body. There is no technology. In many medical institutions, when a diagnosis using a medical image is performed, a radiographer or the like is requested to take a necessary medical image based on an inquiry of a patient by a doctor. When receiving a request, a radiographer or the like, when imaging a patient, plans imaging in an order that facilitates imaging from the patient's body position or the like. However, the order in which radiographers and the like are easy to take an image does not necessarily match the order in which doctors and the like are easy to observe. Therefore, a medical image processing apparatus is provided that changes the display order when displaying captured images (for example, Patent Document 1).

  In recent years, the environment surrounding medical care has been rapidly digitized and acquired by the Radiology Information System (RIS), which is an ordering system that processes examination requests from doctors via an electronic network, and modality equipment. A centralized medical image management system (PACS: Picture Archiving and Communication Systems) that stores stored images as electronic data has been developed. The examination request from the doctor is transmitted to each modality device via the RIS. On the modality apparatus side, an imaging plan corresponding to the inspection request is automatically generated, and a radiographer or the like executes imaging based on the imaging plan. Furthermore, the imaging plan is also transmitted to the PACS and used when a doctor or an interpreting doctor makes a diagnosis. Thus, the imaging plan automatically generated in the modality apparatus is called PAS (Programmable Anatomical Scans). The PAS is composed of a plurality of imaging units, and is created for each anatomical part to be imaged. There has been provided an image diagnostic apparatus capable of accumulating such a PAS as a database and automatically acquiring an appropriate imaging plan on the modality apparatus side (for example, Patent Document 2).

JP 2004-283325 A JP 2012-157688 A

  However, for reasons related to safety and quality, the modality device checks the hardware and acquired images each time each imaging unit is executed. If there is an abnormality, the imaging order set in the PAS is used. There are cases where measures are taken such as switching and imaging, or imaging an already completed imaging unit again.

  For example, in the case of a magnetic resonance imaging apparatus, a high frequency signal (RF signal) is applied to a subject to obtain a magnetic resonance signal. The application of the high frequency signal heats the subject and raises the body temperature of the subject. Therefore, from the viewpoint of safety, SAR (Specific Absorption Ratio) is defined as energy absorbed per unit mass of the subject, and the upper limit value of SAR, that is, the safety standard value is IEC (International Electrotechnical Commission) standard (IEC 60601). 2-33). Due to such safety standard restrictions, when imaging is performed according to the imaging plan registered in the PAS, it is necessary to provide a time during which imaging is not performed for a predetermined time so that the patient's body temperature does not rise too much. Loss may occur. Therefore, the imaging order is actually changed on the magnetic resonance imaging apparatus side, and imaging is performed in an imaging order so that the SAR does not exceed the reference value. In addition, depending on the available capacity of the hard disk, the deterioration state of the gradient magnetic field coil, the imaging order may be changed in consideration of efficiency. Furthermore, when an artifact occurs due to factors such as patient movement, the imaging unit must be re-imaged. When re-imaging is performed, it is necessary to employ only an image selected from a plurality of acquired images for diagnosis.

  The change or addition of the imaging order as described above occurs unintentionally, and occurs in real time in one continuous examination composed of a plurality of imaging units. If the information regarding the change in the imaging order is not correctly transmitted, the doctors and the like make a diagnosis based on the recognition that the imaging has been executed as described in the PAS, resulting in confusion. In addition, in order to communicate with a radiographer or the like, a number indicating an imaging order called a series number is often used. The series numbers are assigned in the order in which the images are actually generated when such an unexpected change in the imaging order is performed. Therefore, since the series number in PAS and the series number of the actually generated image are different, a situation occurs in which communication cannot be performed correctly. Conventionally, when such a change in imaging order or re-imaging occurs, the image after imaging is displayed on an imaging device, etc., and a radiographer or the like manually changes the imaging order or deletes unnecessary images. I was doing work called imaging. However, such imaging requires the installation of dedicated imaging devices and software, and a space for installing these devices, and the time costs of a radiographer who performs the imaging are necessary. It was.

  Thus, there is a demand for a magnetic resonance imaging apparatus having a function of rearranging and transmitting images in the order registered in the imaging plan when an unexpected imaging order change occurs.

  The magnetic resonance imaging apparatus according to the present embodiment includes an imaging plan storage unit in which a plurality of imaging plans composed of a plurality of imaging units are accumulated, and a plurality of imaging plans based on an examination request for the subject. An imaging management unit that selects an appropriate imaging plan from the above and manages at least one of execution and safety and quality in the imaging for each imaging unit constituting the selected imaging plan, and the selected An imaging order change that changes the imaging order in the selected imaging plan in accordance with the management of at least one of safety and quality in imaging, and an imaging unit that acquires an image for each imaging unit constituting the imaging plan And an acquired image order changing unit that rearranges the images acquired by the imaging unit based on the selected imaging plan.

1 is a conceptual configuration diagram illustrating an example of a magnetic resonance imaging apparatus according to an embodiment. 1 is a functional block diagram showing an example functional configuration of a first embodiment of a magnetic resonance imaging apparatus according to an embodiment. FIG. 5 is a flowchart showing an example of the operation of the first embodiment of the magnetic resonance imaging apparatus according to the embodiment. The figure explaining the judgment method whether the upper limit of the SAR safety standard is exceeded in 1st Embodiment of the magnetic resonance imaging apparatus which concerns on embodiment. The figure explaining the change of the imaging order by the SAR upper limit in 1st Embodiment of the magnetic resonance imaging apparatus which concerns on embodiment. The figure explaining the method to search the series number of PAS from the imaging unit ID of the acquisition image in 1st Embodiment of the magnetic resonance imaging device which concerns on embodiment. The figure explaining rearrangement of the acquisition picture in a 1st embodiment of a magnetic resonance imaging device concerning an embodiment. The functional block diagram which shows the function structural example of the 2nd Example of the magnetic resonance imaging device which concerns on embodiment. 9 is a flowchart showing an example of the operation of the second embodiment of the magnetic resonance imaging apparatus according to the embodiment. The figure explaining the change of the imaging order by re-imaging in 2nd Embodiment of the magnetic resonance imaging device which concerns on embodiment. The figure explaining the imaging execution plan of the state in which the imaging in 2nd Embodiment of the magnetic resonance imaging device which concerns on embodiment was completed. The figure explaining the method to search the series number of PAS from the imaging unit ID of the acquisition image in 2nd Embodiment of the magnetic resonance imaging device which concerns on embodiment. The figure explaining rearrangement of the acquisition picture in a 2nd embodiment of a magnetic resonance imaging device concerning an embodiment. The figure explaining the selection method of the re-captured image in 2nd Embodiment of the magnetic resonance imaging device which concerns on embodiment.

  Embodiments of a magnetic resonance imaging apparatus according to the present invention will be described with reference to the accompanying drawings.

(1) Configuration FIG. 1 is a conceptual configuration diagram illustrating an example of a magnetic resonance imaging apparatus according to an embodiment. As shown in FIG. 1, a magnetic resonance imaging apparatus 100 according to the embodiment includes an imaging unit 8 and a computer 7, and the imaging unit 8 is positioned in a static magnetic field power source 1 that generates a static magnetic field. Gradient magnetic field power supply 2 (2X, 2Y, 2Z) for adding information, RF receiver 3 and RF transmitter 4 for transmitting and receiving high-frequency signals, SAR measuring device 5, sequence controller 6 for executing a predetermined pulse sequence, The configuration includes a bed portion 9 on which a specimen P (patient) is placed and a magnet mount 10. The computer 7 is configured to control the entire magnetic resonance imaging apparatus 100.

  The magnet mount 10 includes a static magnetic field magnet 11, a gradient magnetic field coil 12, an RF coil 13, and the like, and these components are housed in a substantially cylindrical gantry.

  The static magnetic field magnet 11 of the magnet mount 10 generates a static magnetic field in a bore (a space inside the cylinder of the static magnetic field magnet 11) that is an imaging region of the subject P. The static magnetic field magnet 11 has a built-in superconducting coil. In the excitation mode, a static magnetic field is generated by applying a current supplied from the static magnetic field power supply 1 to the superconducting coil. Thereafter, when the mode is changed to the permanent current mode, the static magnetic field power source 1 is disconnected. In the static magnetic field magnet 11, the superconducting coil is cooled to a very low temperature by liquid helium, and is cooled by the liquid helium for maintaining a heat shield for keeping the inside of the static magnetic field magnet 11 at a very low temperature.

  The gradient magnetic field coil 12 also has a substantially cylindrical shape and is fixed inside the static magnetic field magnet 11. The gradient magnetic field coil 12 applies a gradient magnetic field in the X-axis, Y-axis, and Z-axis directions by a current supplied from the gradient magnetic field power supply 2 (2Y, 2Y, 2Z).

  The SAR measuring device 5 measures the amount of energy (SAR) absorbed by the subject P from the RF signal actually output by the RF transmitter 4. The measured SAR is transmitted to the computer 7 via the sequence controller 6.

  The sequence controller 6 controls imaging conditions in the imaging unit 8 of the magnetic resonance imaging apparatus 100. The sequence controller 6 controls the imaging sequence based on the imaging conditions set for each imaging unit. The imaging sequence is executed by the sequence controller 6 controlling the RF receiver 3 and the RF transmitter 4 according to the imaging conditions registered in the PAS.

  The computer 7 includes a main control unit 20, an input unit 30, a display unit 40, a storage unit 50, a communication control device 60, and the like as its internal structure. Based on the inspection request acquired from the RIS 200 via the communication control device 60, a PAS corresponding to the inspection request is selected from a database storing a plurality of PASs stored in the storage unit 50. Based on the selected PAS, the program stored in the storage unit 50 is executed by the main control unit 20 having a processor, so that the sequence controller 6 executes the imaging sequence in accordance with the imaging conditions registered in the PAS. Further, the main control unit 20 executes the program stored in the storage unit 50, so that the energy (SAR: RF signal) absorbed in 1 kg of the living tissue of the subject P from the set imaging conditions and the actually measured SAR value. Specific Absorption Ratio) and the like are calculated, and the sequence controller 6 is requested to change the imaging order so that imaging is performed within safety standards. Further, the computer 7 acquires the data acquired from the RF receiver 3 via the sequence controller 6, evaluates image reconstruction and image quality, and captures the imaging unit that needs re-imaging to the sequence controller 6. Request. The images acquired in this manner are edited in order by the program stored in the storage unit 50 of the computer 7 being executed by the main control unit 20, and transmitted to the PACS 300 via the communication control device 60. The

  The storage unit 50 includes a storage medium such as a RAM and a ROM, and includes a storage medium readable by the main control unit 20 such as a magnetic or optical storage medium or a semiconductor memory.

  The input unit 30 is configured by a general input device such as a keyboard, a touch panel, a numeric keypad, and a mouse.

  The display unit 40 is configured by a general display device such as a liquid crystal display or an OLED (Organic Light Emitting Diode) display, for example, and displays an imaging order, a calculated SAR, and the like according to control of the main control unit 20.

  The communication control device 60 implements various information communication protocols according to the network form. The communication control device 60 is connected to the magnetic resonance imaging apparatus 100 and an external storage device such as the RIS 200 and the PACS 300 and other electric devices according to these various protocols. For this connection, an electrical connection via an electronic network can be applied. Here, the electronic network means an entire information communication network using telecommunications technology. In addition to a wireless / wired LAN such as a hospital backbone LAN and an Internet network, a telephone communication line network, an optical fiber communication network, a cable communication network, Includes satellite communications networks.

(2) Operation Regarding the operation of the magnetic resonance imaging apparatus 100 according to the present embodiment, the control related to the SAR safety reference value and the execution of re-imaging are the factors that cause the change in the imaging order of the imaging units registered in the PAS. As an example, control related to the SAR safety reference value will be described as “first embodiment”, and control related to execution of re-imaging will be described as “second embodiment”.

(First embodiment)
FIG. 2 is a functional block diagram illustrating a functional configuration example of the first embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. The first embodiment relates to a case where the imaging order is changed by the control related to the SAR safety reference value.

  As illustrated in FIG. 2, the magnetic resonance imaging apparatus 100 includes an imaging plan storage unit 51, an imaging management unit 21, a SAR calculation unit 23, an imaging order change unit 25, an acquired image order change unit 27, and a display unit 40. Among them, the imaging management unit 21, the SAR calculation unit 23, the imaging order change unit 25, and the acquired image order change unit 27 are functions realized by executing a program stored in the storage unit 50 via the main control unit 20. is there.

  The imaging plan storage unit 51 is a database that includes a plurality of imaging units, and stores a plurality of imaging plans called PAS created for each anatomical region.

  The imaging management unit 21 receives an examination request from a doctor or the like via the RIS 200 that is an ordering system, and selects a PAS corresponding to the examination request from the imaging plan storage unit 51. As a PAS selection method corresponding to the examination request, for example, an “anatomical part” and an “imaging method” to be imaged by the patient are acquired from the examination request, and the database of the imaging plan storage unit 51 is used as a key. It may be selected by a general database search method such as selecting by searching, or may be a method described in Patent Document 2. In the imaging management unit 21, an appropriate PAS corresponding to the inspection request is extracted from the imaging plan storage unit 51.

  Further, the imaging management unit 21 generates an “imaging execution plan” based on the information registered in the selected PAS, and causes the imaging unit 8 to perform imaging. The imaging execution plan generated by the imaging management unit 21 is a copy of the imaging plan registered in the PAS, and is information including at least an imaging order necessary for imaging, an imaging unit name, an imaging unit ID, and an imaging condition. . Imaging is executed for each imaging unit according to an imaging execution plan. In the first embodiment, verification based on the SAR safety standard is performed for each imaging unit. In addition, the imaging execution plan is displayed on the display unit 40.

  The SAR calculation unit 23 calculates a 6-minute average SAR, a 10-second average SAR, and the like. The 6-minute average SAR and the 10-second average SAR are calculated based on the actual SAR value measured by the SAR measuring device 5. The 6-minute average SAR is the average value of the latest 6 minutes of the actual SAR value acquired by the SAR measuring device 5. Similarly, the 10-second average SAR is an average value of the latest 10 seconds of the actual SAR value acquired by the SAR measuring device 5. Further, the SAR calculation unit 23 is based on the actually measured SAR value acquired by the SAR measuring device 5, such as a 6-minute average SAR of already executed imaging units, a predicted SAR value after a certain period of time, or an unimplemented imaging unit It is possible to calculate the SAR predicted value when the above is executed.

  The imaging management unit 21 monitors imaging based on the value calculated by the SAR calculation unit 23 so as not to exceed the upper limit value determined by the safety standard. As a method thereof, it is determined whether or not the predicted value when a certain time period calculated by the SAR calculation unit 23 elapses or when an unexecuted imaging unit is executed exceeds the upper limit value defined by the safety standard, When the predicted value exceeds the safety standard, the imaging order changing unit 25 is caused to change the imaging order of the imaging execution plan. The changed imaging execution plan is displayed on the display unit 40. A method for changing the imaging order in the imaging order changing unit 25 will be described later.

  The acquired image order changing unit 27 rearranges the images acquired by the imaging unit 8 based on the imaging order registered in the PAS. The image generated by the imaging unit 8 is given, as supplementary information, at least a series number indicating the order of actual imaging of a plurality of imaging units and an imaging unit ID that uniquely identifies the imaging unit. Here, the incidental information is defined in the DICOM (Digital Imaging and Communication in Medicine) standard, which is defined as a global standard for handling images captured by different modality devices using standardized data formats and communication methods. The stored data area stores information such as image identification information and patient information. The PAS is data including at least a series number indicating an imaging order of a plurality of imaging units, an imaging unit ID that uniquely identifies the imaging unit, and an imaging condition of the imaging unit. The imaging unit ID of the auxiliary information of the image and the imaging unit ID of the PAS are common information, and the acquired image order changing unit 27 acquires the PAS series number using the imaging unit ID as a key, and rearranges the acquired images. . The rearranged images are transmitted to an external storage device such as PACS300. The rearrangement method in the acquired image order changing unit 27 will be described later.

  FIG. 3 is a flowchart illustrating an example of the operation of the first embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment.

  In ST101, the imaging management unit 21 selects a PAS corresponding to the inspection request from the imaging plan storage unit 51, and generates an imaging execution plan based on the PAS.

  In ST103, the imaging unit 8 determines whether all imaging has been completed for the imaging units constituting the imaging execution plan, and sequentially executes imaging until the imaging is completed (ST105).

  In ST107, based on the actual SAR value acquired by the SAR measuring device 5, the SAR of the imaging unit for which the SAR calculation unit 23 has been executed and the predicted SAR value for the unimplemented imaging unit are calculated. It is determined whether the upper limit value of the SAR safety standard has been exceeded.

  In ST109, the imaging order changing unit 25 changes the imaging order so that the upper limit value of the SAR safety standard is not exceeded.

  In ST111, data acquired by imaging is reconstructed and an image is acquired.

  FIG. 4 is a diagram illustrating a method for determining whether the upper limit value of the SAR safety standard is exceeded in the first embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. FIG. 4A shows a table illustrating an imaging execution plan generated from the PAS according to the inspection request by the imaging management unit 21. In the imaging execution plan table, “series number”, “imaging unit name”, “6-minute average SAR”, “individual SAR”, “time”, and “situation” indicating the execution status of the imaging unit are described from the left. Has been.

  The imaging execution plan of FIG. 4A describes five imaging units, and the first-stage series number “1000” (imaging unit name: “Locator 3 Axis”) is, for example, the X direction and the Y direction. , One Z-direction positioning image is taken for 2 minutes (“2:00” in the “time” column). The second series number “2000” (imaging unit name: “Shimming”) indicates that imaging for adjusting the magnetic field uniformity and the like is performed for 3 minutes (“3:00” in the “time” column). Show. The third-stage series number “3000” (imaging unit name: “3D TOF”) takes 3 minutes of imaging by the TOF (Time of Flight) method in order to obtain a three-dimensional image (“3: 00 ") indicates that an image is to be captured. Similarly, for example, for the fourth stage series number “4000” (imaging unit name: “T1W AX”), T1-weighted imaging of the axial surface is performed for 4 minutes (“4:00” in the “time” column). Is shown. The fifth series number “5000” (imaging unit name: “T2W AX”) indicates that T2-weighted imaging of the axial surface is performed for 2 minutes (“2:00” in the “time” column).

  As described above, SAR (unit: W / kg) is defined as the energy of the RF signal absorbed in 1 kg of living tissue, and the energy of the RF signal absorbed in 1 kg of living tissue in the latest 6 minutes. Is a 6-minute average SAR (W / kg). On the other hand, the individual SAR is a value obtained by dividing the energy of the RF signal absorbed by 1 kg of the living tissue by the imaging time T when an individual imaging unit is continued for the imaging time T. When imaging of a certain imaging unit having a predetermined pulse sequence is performed for the imaging time T, the energy of the RF signal absorbed by 1 kg of the living tissue increases as the imaging time T becomes longer. The divided value is a value that does not depend on the imaging time T, and indicates an individual average SAR size (ie, RF signal energy intensity) for each imaging unit. This value is defined as an individual SAR.

  The 6-minute average SAR and the individual SAR shown in FIG. 4A are values calculated by the SAR calculation unit 23. In an imaging unit in which the status is “completed”, an actual SAR based on the actual SAR value is used. In an imaging unit that is a value and the status is “in execution” or “not yet”, the SAR calculation unit 23 is calculated based on the actual SAR value acquired in the already executed imaging unit, the imaging condition of the imaging unit to be executed, and the like. Is the predicted SAR value. The 6-minute average SAR and the individual SAR shown in FIG. 4A are “0.33” and “1.00” for the first “Locator 3 Axis”, “1.25” and “1.25” for the second “Shimming”, respectively. 1.50, 3rd TOF “1.63”, “1.75”, 4th “T1W AX” “2.05”, “2.20”, 5th “T2W AX” “1.88” “1.25”.

  FIG. 4B is a graph showing the transition of the 6-minute average SAR calculated by the SAR calculation unit 23. The vertical axis indicates the 6-minute average SAR value (W / kg) of actual measurement and prediction calculated by the SAR calculation unit 23, and the horizontal axis indicates time (minutes). As illustrated in the table of FIG. 4A, a 6-minute average SAR transition in a state where the “3D TOF” in the third row is being executed is illustrated. As shown in the graph of FIG. 4B, the graph indicated by the solid line is a graph based on the 6-minute SAR calculated for the executed imaging unit. Further, the graph indicated by the broken line is a graph showing the predicted value of the 6-minute average SAR after the imaging is completed based on the actually measured SAR value for the “3D TOF” in the third stage being executed. . The graph shown by the one-dot chain line shows the case where the fourth-stage “T1W AX” and the fifth-stage “T2W AX” predicted from the SAR actual measurement value and the imaging conditions acquired in the previous imaging unit are executed. It is a graph which shows the predicted value of 6 minute average SAR. As shown in the graph of FIG. 4B, when the safety reference value of SAR is 2.0 W / kg, the “T1W AX” of the fourth stage scheduled to be executed next in the table of FIG. The predicted value of the 6-minute average SAR exceeds the safety standard value. Therefore, the imaging management unit 21 determines that imaging cannot be executed in the same imaging order, and requests the imaging order change unit 25 to change the imaging execution plan.

  FIG. 5 is a diagram for explaining a change in the imaging order based on the SAR upper limit value in the first embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. FIG. 5A shows a table illustrating an imaging execution plan, as in FIG. FIG. 5B is also a graph of measured values and predicted values of the 6-minute average SAR calculated by the SAR calculation unit 23, as in FIG. 4B.

  The table in FIG. 5A is different from the table in FIG. 4A in that the imaging order of the imaging units in the fourth stage and the fifth stage is switched. In the example of FIG. 5, the 6-minute average SAR predicted value after the order change is obtained as shown by the two-dot chain line in FIG. As a result, the increase becomes moderate as compared to before the change, and continuous imaging can be performed without exceeding the upper limit value of the SAR safety reference value.

  As shown in FIG. 4A and FIG. 5A, even when the imaging order of the imaging units is changed, the series number is a number indicating the imaging order. Will not occur, but will be numbered in ascending order in which imaging is performed. That is, the imaging unit name “T1W AX” of the series number “4000” shown in the fourth row in FIG. 4A is shown in the fifth row in the table of FIG. “5000” is newly assigned. Similarly, the imaging unit name “T2W AX” of the series number “4000” shown in the fifth row in FIG. 4A is advanced in the fourth row in FIG. 5A, and the series number is “4000” is newly assigned.

  As shown in FIG. 5, when the order of the imaging units executed in the imaging execution plan is changed, the series numbers are assigned in ascending order according to the order. Doctors who diagnose or interpret images observe images based on the imaging order registered in the PAS, so the series number of the acquired images is different from what is assumed, and work to confirm with the radiographer who performed the imaging occurs To do. 4A and 5A are displayed on the display unit 40, and if such a change in order occurs, the fact that there has been a change in order in the past is indicated as radiation. Engineers etc. recorded manually. Then, based on the recording, it is necessary to transmit the information that the change of the imaging order has occurred to a doctor or the like, or to change the order with an imaging apparatus provided separately. Furthermore, depending on the setting of the magnetic resonance imaging apparatus 100, the imaging order may be automatically changed, and therefore, there is a possibility that the information on the order change is leaked. In such a case, trying to communicate between the doctor and the radiologist based on the series number and the order of the images will cause confusion, and the reliability of the acquired image information cannot be guaranteed. It can also be a thing. Further, the imaging unit name is often indicated by a character string “T1” for the T1-weighted image, a character string “T2” for the T2-weighted image, or an abbreviation. Therefore, when transmitting information or manually changing the imaging unit, the character string “T1” indicating the T1-weighted image and the character string “T2” indicating the T2-weighted image are misidentified. Human error can occur.

  Therefore, the magnetic resonance imaging apparatus 100 according to the present embodiment, when the order of images is changed due to a change in imaging order that occurs for each patient or individual examination, as in the SAR safety standards, The order is rearranged in the imaging order registered in the PAS and transmitted to an external storage device such as the PACS 300. Thereby, a user such as image interpretation can observe and diagnose an image output from the magnetic resonance imaging apparatus 100 without using an imaging apparatus or the like.

  In ST113 of FIG. 3, the acquired image order changing unit 27 rearranges the images acquired in the order registered in the imaging execution plan after the order change into the order registered in the PAS. Obtained from the storage unit 51.

  In ST115, the acquired image order changing unit 27 rearranges the acquired images in the order registered in the PAS. The accompanying information of the acquired image includes an imaging unit ID for uniquely specifying the imaging unit. The images are rearranged by acquiring a series number corresponding to the imaging unit ID from the imaging plan registered in the PAS using the imaging unit ID as a key.

  In ST117, the acquired image order changing unit 27 transmits the rearranged images to an external storage device such as the PACS 300 via the electronic network.

  FIG. 6 is a diagram illustrating a method for searching for the PAS series number from the imaging unit ID of the acquired image in the first embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. (A) of FIG. 6 is a table | surface which shows the information of the imaging plan registered into PAS. 6A, from the left, “series number”, “imaging unit name”, “imaging unit ID”, multiple imaging conditions (“imaging condition 1 (imaging time)”, “imaging condition 2 (flip angle) )")It is shown. The order of the imaging units is the same as the order of the imaging execution plans generated by the imaging management unit 21 shown in FIG. The imaging unit ID shown in FIG. 6A is a code given to uniquely identify the imaging unit, and is an internal code composed of a combination of alphabets and numbers. Although FIG. 6A illustrates an example in which the imaging unit ID is composed of four alphabetic characters, the present invention is not limited to this, and is not limited as long as the code system can uniquely identify the imaging unit. Since this imaging unit ID is held in a state associated with the imaging unit, as shown in FIGS. 4 and 5, even when the order of the imaging unit is changed, the related imaging unit is specified. can do.

  The table in FIG. 6B shows the accompanying information of the image. From the left, “series number”, “imaging unit name”, and “imaging unit ID” are shown. The supplementary information of the image shown in the table of FIG. 6B is an image captured in the order registered in the imaging execution plan after being changed by the imaging order changing unit 25 shown in FIG. . Therefore, compared to FIG. 6A, in the table of FIG. 6B, the fourth row is “T2W AX” and the fifth row is “T1W AX”, and the order of the imaging units is changed. Yes.

  The table in FIG. 6C shows the result of searching the series number of the PAS in FIG. 6A using the imaging unit ID in the table in FIG. 6B as a key. As described above, compared to the PAS imaging order, the order of the acquired images is changed at the fourth and fifth stages. Therefore, the PAS series number corresponding to the imaging unit ID of the image auxiliary information acquired using the imaging unit ID of the image auxiliary information as a key is “5000” in the fourth row as shown in the table of FIG. "5th stage is" 4000 ". By rearranging the images so that the PAS series numbers are in ascending order, the images can be rearranged in the order registered in the PAS.

  FIG. 7 is a diagram for explaining rearrangement of acquired images in the first embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. FIG. 7 shows, from above, the series number of the PAS acquired based on the imaging unit ID of the supplementary information of the image shown in FIG. 6C, the series number of the supplementary information of the image, the order of the acquired images, and the acquisition after the rearrangement. The order of images is shown. Similar to FIG. 6, the acquired images are acquired in the order in which the fourth from the left is (T2W AX) and the fifth (T1W AX) is compared with the order registered in the PAS. ing. By changing the order of the acquired images as indicated by the arrows in accordance with the series number of the top PAS, the order of the rearranged images is (T1W AX) and the fifth (T2W) AX).

  In the first embodiment, the safety standard of 6-minute average SAR has been described, but the same applies to the safety standard of 10-second average SAR.

  As described above, when the imaging order is changed during the inspection due to the restriction of the SAR safety standard, the acquired images are rearranged in the order registered in the PAS and output to the PACS 300 or the like. Therefore, it is possible to save human costs such as the cost of introducing the image inspection apparatus and the time required for image inspection. Further, even if the change of the imaging order occurs due to circumstances on the side of the modality apparatus such as the magnetic resonance imaging apparatus 100 and the order of the acquired images is changed, the order of the acquired images is initially planned in the modality apparatus. Images can be handled seamlessly by rearranging the images in the order of imaging and outputting them to other devices.

(Second Embodiment)
The second embodiment relates to control related to execution of re-imaging in the magnetic resonance imaging apparatus 100. The re-imaging occurs, for example, when an artifact occurs in the image due to body movement of the subject P, deterioration of the gradient magnetic field coil, or the like. The re-imaging may be set manually by confirming an image acquired by a radiographer or the like who performs imaging, or the re-imaging may be set by automatically detecting an artifact.

  FIG. 8 is a functional block diagram illustrating a functional configuration example of the second example of the magnetic resonance imaging apparatus 100 according to the embodiment. This embodiment differs from the first embodiment shown in FIG. 2 in that a re-imaging determination unit 29 is provided instead of the SAR calculation unit 23. The re-imaging determination unit 29 is a function realized by executing a program stored in the storage unit 50 under the control of the main control unit 20.

  The re-imaging determination unit 29 acquires imaging data from the imaging unit 8 and determines whether or not re-imaging is necessary for the imaging unit based on a determination criterion such as the presence or absence of an artifact. The presence or absence of the artifact may be determined by, for example, displaying a reconstructed image on the display unit 40 and visually confirming by a radiographer or the like, or may be automatically determined by analyzing imaging data. . When re-imaging is necessary, information on the imaging unit to be re-imaged is transmitted to the imaging order changing unit 25, and the imaging order changing unit 25 edits the imaging execution plan.

  FIG. 9 is a flowchart illustrating an example of the operation of the second embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. In FIG. 9, only different points from the first embodiment will be described. Process steps common to FIG. 3 for explaining the flowchart of the first embodiment and FIG. 9 are denoted by the same numbers.

  In ST151, the re-imaging determination unit 29 determines whether re-imaging is necessary.

  In ST153, the imaging order changing unit 25 adds an imaging unit that requires re-imaging to the effective imaging unit.

  In ST155, the imaging order changing unit 25 changes the imaging order by adding an imaging unit to be re-imaged.

  In ST157, the acquired image order changing unit 27 selects an output image to be used when transmitting the acquired image from the magnetic resonance imaging apparatus 100 to another external storage device such as the PACS 300.

  In ST159, the acquired image order changing unit 27 rearranges the images in the order of the imaging units registered in the PAS including the images to be used.

  FIG. 10 is a diagram illustrating the change of the imaging order by re-imaging in the second embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. FIG. 10A shows the same imaging unit and imaging order as the imaging execution plan shown in FIG. A difference from FIG. 4 is that a column of “re-imaging necessity” indicating the necessity of re-imaging of an image as a determination result is shown instead of displaying a value such as a 6-minute average SAR. Regarding the necessity of re-imaging, “necessary” is displayed when re-imaging is necessary, and “unnecessary” is displayed when it is not necessary. In the table illustrated in FIG. 10A, the re-imaging determination unit 29 determines that re-imaging is necessary in the imaging of the third-stage imaging unit “3D TOF”, and “necessary” is indicated. Further, it is shown that the imaging unit “T1W AX” in the fourth row is in a “running” state. Therefore, the imaging order changing unit 25 changes the imaging execution plan in order to execute again the third-stage imaging unit “3D TOF” that needs reimaging.

  FIG. 10B shows a changed imaging execution plan in which “3D TOF” for performing re-imaging is added to the imaging execution plan and the imaging order is changed. FIG. 10B illustrates an example in which the imaging unit “T1W AX” that is being executed as the imaging unit to be re-imaged is added immediately after the completion of the imaging unit “T1W AX”. The added imaging unit “3D TOF (re-imaging)” is indicated by shading and added to the fifth row. Since the imaging unit “3D TOF (re-imaging)” is added to the fifth stage, the series number is assigned “5000”. In the imaging unit “T2W AX” in which the series number is “5000” in FIG. 10A, the series number is moved down to “6000” because “3D TOF (re-imaging)” is inserted in the fifth row. Is newly assigned. In addition, although the example in which the added imaging unit is added after the imaging unit being executed is illustrated in FIG. 10, the imaging unit may be added at the end of the imaging unit that has not been executed. In this rearrangement, the imaging order may be determined by determining whether or not the SAR safety reference value shown in the first embodiment is exceeded.

  FIG. 11 is a diagram illustrating an imaging execution plan in a state where imaging in the second embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment is completed. FIG. 11 illustrates an example in which all imaging is performed according to the imaging execution plan in which the imaging sequence change by re-imaging illustrated in FIG. 10B is performed. Since all imaging has been completed, all the “situation” columns are “done”. In addition, “necessary” or “unnecessary” is displayed in the “re-imaging necessity” column. In the example of FIG. 11, an example in which there is no problem in the image quality of an image acquired by “3D TOF (re-imaging)” added in the fifth row is shown. Therefore, the acquired image order changing unit 27 uses the image acquired at the fifth level instead of the image acquired at the third level imaging unit, and finally generates data to be output to the PACS 300 or the like.

  FIG. 12 is a diagram illustrating a method for searching for the PAS series number from the imaging unit ID of the acquired image in the second embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment.

  FIG. 12A is the same table as FIG. 6A, and is a table showing imaging plan information registered in the PAS. FIG. 12B is a table showing the incidental information of the image, as in FIG. FIG. 12B includes re-imaging necessity information in addition to FIG. The re-imaging necessity information is information given by determining whether or not re-imaging is necessary in the re-imaging determination unit 29, and information “necessary” is given to the imaging unit determined to require re-imaging. . In the example of FIG. 12B, character strings such as “unnecessary” and “necessary” are shown. However, numbers and character strings such as “0”, “1”, “True”, and “False” are used. The symbol is not limited as long as the symbol can determine whether or not re-imaging is necessary. In addition, the imaging unit ID in FIG. 12B is different from FIG. 6B in that a code in which one alphabet and a number are combined with four alphabets is added. This code is a code indicating whether or not it is a re-imaged unit. In the example of FIG. 12B, “Z” indicates the initial imaged unit, “R” indicates re-imaged, and these The numbers given next to the alphabets indicate the number of times of imaging. For example, in the case of re-imaging, “R0” is given, and re-imaging necessity information is “necessary” for the image acquired in the re-imaging. Will be given “R1”. Also, for example, if a PAS imaging plan includes a plurality of imaging units of the same type executed under the same imaging conditions, codes such as “Z0” and “Z1” are registered in the order registered in the PAS. By being given, each imaging unit can be uniquely specified.

  FIG. 12C shows the result of searching for the PAS series number in FIG. 12A using the imaging unit ID in FIG. 12B as a key, as in FIG. 6C. As described above, in the acquired image order changing unit 27, as in the first embodiment, the series number corresponding to the imaging unit ID registered in the PAS can be searched using the imaging unit ID of the auxiliary information of the image as a key. it can. In the example of FIG. 12, the imaging unit ID of the third stage imaging unit in FIG. 12B is “CCCC Z0”, and the imaging unit ID of the fifth stage imaging unit that is the re-imaging unit is “CCCC R0”. It is. When “R” is included in the imaging unit ID, the PAS imaging unit ID is searched for “CCCC” on the left side of R to indicate that re-imaging has been executed. Accordingly, it can be seen that the imaging unit ID of the third stage imaging unit and the PAS series number of the fifth stage imaging unit in FIG. 12B are “3000”. In this way, the series numbers of the imaging units that have undergone re-imaging are the same. Note that when image rearrangement is executed, the images used for the rearrangement are selected in advance, so even if the series numbers are the same as a result of re-imaging, the number of images is finally changed to one series number. Is assigned one image.

  FIG. 13 is a diagram for explaining rearrangement of acquired images in the second embodiment of the magnetic resonance imaging apparatus according to the embodiment. FIG. 13 is similar to FIG. 7, from the top, the PAS series number acquired based on the imaging unit ID of the image supplementary information shown in FIG. 12C, the series number of the supplementary information of the image, and re-imaging necessity information The order of acquired images and the order of acquired images after rearrangement are shown. Similar to FIG. 12, the acquired image has “required” whether or not the third imaging unit “3D TOF” from the left is “necessary” as compared with the order registered in the PAS, and the re-imaging determination unit 29 An example is shown in which re-imaging is further requested, and the imaging unit “3D TOF (re-imaging)” is added to the fifth, and the imaging order of the imaging unit “T2W AX” is lowered accordingly. ing.

  As shown in the re-imaging necessity information in FIG. 13, the re-imaging necessity of the third imaging unit “3D TOF” is “necessary” and is used as an image output from the magnetic resonance imaging apparatus 100. Not suitable for. On the other hand, the necessity of re-imaging of the imaging unit “3D TOF (re-imaging)” acquired as the fifth is “unnecessary”, which is suitable for use. As described above, when the acquired image requests re-imaging, the acquired image order changing unit 27 can select an image that is finally determined not to require re-imaging as a use image. In this way, by selecting the image to be used on the basis of the necessity of re-imaging, and switching the order of the acquired images as indicated by the arrows in accordance with the series number of the top PAS, as in FIG. The order of images can be changed. In the example of FIG. 13, instead of the third “3D TOF” image, the fifth “3D TOF (re-imaging)” image is arranged, and then the fourth acquired “T1W” By arranging the image “AX” and then the image “T2W AX”, the images can be rearranged in the imaging order registered in the PAS.

  FIG. 13 shows an example in which whether or not re-imaging determined by the re-imaging determination unit 29 is necessary is used for selecting an image to be finally output. It can also be determined visually by a radiologist or the like.

  FIG. 14 is a diagram illustrating a method for selecting a re-captured image in the second embodiment of the magnetic resonance imaging apparatus 100 according to the embodiment. FIG. 14 shows an example in which the imaging unit that needs re-imaging is added to the imaging execution plan and all imaging is performed, as in the table shown in FIG. In addition to the table of FIG. 11, a “selection” column is added to the table of FIG. 14, and an example that can be selected by checking a check box of an image used for rearrangement is shown. Checking this check box displays, for example, a re-imaging necessity information that is “unnecessary” with a check in advance, and the user, such as a radiologist, confirms the state and selects an image to be used. May be. For example, if you want to use the third-stage “3D TOF” image by comparing the third-stage “3D TOF” image with the fifth-stage “3D TOF (re-imaging)” image, as determined by a radiologist, etc. An operation of checking on the third level and removing the check on the fifth level may be performed from the input unit 30. In addition, in the example of FIG. 13, the “select” check box is shown for all images, but only the image that is the target of re-imaging may be displayed and displayed so as to be selected. . Furthermore, since the first and second-stage “Locator 3 Axis” and “Shimming” images may not be used for interpretation or diagnosis, check the display illustrated in FIG. May be selected, and rearrangement may be performed using only the selected image.

  As described above, when the imaging order is changed during the examination execution due to the request for re-imaging, the acquired images are rearranged in the order registered in the PAS and output to the PACS 300 or the like, thereby enabling the first embodiment. As with, the cost of image inspection can be saved. Further, when re-imaging is performed, only necessary images are extracted and rearranged, so that images output from the magnetic resonance imaging apparatus 100 do not include unnecessary images, and only necessary images are included. Since it can be output, human error such as confusion and erroneous deletion can be prevented. Furthermore, the reduction in data amount leads to an improvement in communication speed by reducing the communication amount from the magnetic resonance imaging apparatus 100 to the PACS 300 and the like.

  Note that the embodiment of the magnetic resonance imaging apparatus 100 according to the present embodiment relates to the control related to the SAR safety reference value and the execution of re-imaging as a factor that causes the change in the imaging order of the imaging units registered in the PAS. Although control was taken as an example, it is not limited to them. This occurs in terms of maintaining the safety and quality of the modality apparatus including the magnetic resonance imaging apparatus 100, for example, checking the free capacity of the hard disk, checking the deterioration of the X-ray tube in the X-ray imaging apparatus or X-ray CT apparatus, etc. Also, a change in the imaging order related to the check of the modality device itself is also assumed as a factor that causes the change in the imaging order.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 Static magnetic field power supply 2 Gradient magnetic field power supply 3 RF receiver 4 RF transmitter 5 SAR measuring device 6 Sequence controller 7 Computer 8 Imaging part 9 Bed part 10 Magnet mount 11 Static magnetic field magnet 12 Gradient magnetic field coil 13 RF coil 20 Main control part 21 Imaging management unit 23 SAR calculation unit 25 Imaging order change unit 27 Acquisition image order change unit 29 Re-imaging determination unit 30 Input unit 40 Display unit 50 Storage unit 51 Imaging plan storage unit 60 Communication control device 100 Magnetic resonance imaging device 200 RIS
300 PACS
P subject

Claims (9)

An imaging plan storage unit in which a plurality of imaging plans composed of a plurality of imaging units are accumulated;
Based on the examination request for the subject, an appropriate imaging plan is selected from the plurality of imaging plans, the imaging is performed for each of the imaging units constituting the selected imaging plan, and the safety and quality in the imaging An imaging management unit that manages at least one of
An imaging unit that obtains an image for each imaging unit constituting the selected imaging plan; and
An imaging order changing unit that changes the imaging order in the selected imaging plan according to the management of at least one of safety and quality in the imaging,
An acquired image order changing unit for rearranging images acquired by the imaging unit based on the selected imaging plan;
A magnetic resonance imaging apparatus comprising: An SAR calculation unit that obtains a SAR (Specific Absorption Ratio) of the imaging unit and calculates an imaging unit in which imaging is performed and a predicted value of the SAR of an imaging unit that has not been performed;
Further comprising
The imaging management unit determines whether the SAR calculated by the SAR calculation unit exceeds a predetermined upper limit value based on a predetermined safety reference value,
When the calculated SAR exceeds the predetermined upper limit value, the imaging order changing unit changes the imaging order of the imaging units that have not been imaged among the imaging units registered in the selected imaging plan. Changing the imaging order so that the SAR does not exceed the predetermined upper limit,
The magnetic resonance imaging apparatus according to claim 1. The predetermined safety standard value is a safety standard value defined for a 6-minute average SAR obtained by averaging the latest 6-minute SAR over 6 minutes;
The magnetic resonance imaging apparatus according to claim 2. A re-imaging determination unit that acquires an image generated for the imaging unit, determines based on the quality of the acquired image, and determines whether or not re-imaging is necessary for the imaging unit;
Further comprising
The imaging management unit determines whether re-imaging is necessary according to whether the re-imaging is necessary,
The imaging order changing unit newly sets an imaging unit having the same condition as the imaging unit as an imaging unit that has not been subjected to imaging among the imaging units registered in the imaging plan for the imaging unit that needs to be re-imaged. To change the imaging order
The magnetic resonance imaging apparatus according to claim 1. The selected imaging plan includes at least a series number indicating an imaging order of the plurality of imaging units, an imaging unit ID that uniquely identifies the imaging unit, and an imaging condition of the imaging unit,
The imaging order changing unit changes the order of imaging units registered in the imaging plan by changing the series number registered in the selected imaging plan,
The magnetic resonance imaging apparatus according to claim 1, wherein: The image acquired by the imaging unit includes, as supplementary information, at least a series number indicating the order in which the plurality of imaging units are actually captured, and an imaging unit ID that uniquely identifies the imaging unit,
The acquired image order changing unit acquires the series number corresponding to the imaging unit ID in the selected imaging plan based on the imaging unit ID of the supplementary information of the image, and the order of the images is selected. The magnetic resonance imaging apparatus according to claim 5, wherein the imaging plan is changed based on a series number of the imaging plan. The image acquired by the imaging unit further includes re-imaging necessity information of the acquired image,
The acquired image order changing unit selects a necessary image from a plurality of images acquired by the re-imaging based on the re-imaging necessity information of the image, and rearranges the images using the selected image. To do the
The magnetic resonance imaging apparatus according to claim 6. A display unit that displays re-imaging necessity information of the image for each imaging unit;
Based on the information on whether or not to re-image the image, information on an image selected from a plurality of images acquired by the re-imaging is input, and an input unit;
Further comprising
The acquired image order changing unit rearranges the images using an image selected based on an input from the input unit;
The magnetic resonance imaging apparatus according to claim 7. Computer
Storage means for storing a plurality of imaging plans composed of a plurality of imaging units;
Based on the examination request for the subject, an appropriate imaging plan is selected from the plurality of imaging plans, and at least one of the execution of imaging and the safety and quality of the imaging is managed for each selected imaging unit. means,
Means for acquiring an image for each imaging unit constituting the selected imaging plan;
Means for changing an imaging order in the selected imaging plan in accordance with at least one management of safety and quality in the imaging;
Means for rearranging the images acquired by the imaging unit based on the selected imaging plan;
Program for magnetic resonance imaging apparatus to function as

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