JP2011000305A - Magnetic resonance imaging system and monitoring method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce degradation of CPU and HDD of a work station having a communication part for reporting an abnormality to the related facilities and to reduce the electric power consumption if the abnormality occurs during a continuous monitoring of an MRI apparatus.SOLUTION: In a magnetic resonance imaging system and a monitoring method, the electric power source of the work station having the communication part for reporting to the related facilities is suitably controlled according to the emergency degree of the abnormal content of the MRI apparatus.

Description

  The present invention relates to a system for monitoring and reporting abnormalities in a magnetic resonance imaging apparatus.

  Liquid helium is used for cooling a superconducting magnet used in a magnetic resonance imaging apparatus. There has been a monitoring system that reports the state of this liquid helium to a maintenance service provider or the like periodically or as needed via the Internet.

JP 2006-222417 A

  The monitoring and reporting system that monitors the magnetic resonance imaging device and notifies related facilities when an abnormality occurs is always turned on even when the magnetic resonance imaging device is not operating. Station degradation and power consumption were problems. Patent Document 1 does not disclose control of the power supply of the communication unit that makes a notification when there is no need to report the state of the magnetic resonance imaging apparatus to the maintenance service provider company or the like from the communication unit of the monitoring system.

  Therefore, an object of the present invention is to provide a magnetic resonance imaging system and a monitoring method capable of reducing deterioration of a workstation and reducing power consumption.

  In order to achieve the above object, the present invention provides a static magnetic field generator that generates a uniform static magnetic field in a space that accommodates a subject, a gradient magnetic field generator that generates a gradient magnetic field superimposed on the static magnetic field, An MRI apparatus provided with a monitoring device that monitors an abnormality of at least one of the static magnetic field generation device and the gradient magnetic field generation device, and means for controlling the MRI device, and receives a signal from the monitoring device. In a magnetic resonance imaging system comprising a workstation provided with a communication unit for reporting to a related facility via a network line, the monitoring device determines that the power supply of the workstation is not energized, and the monitoring device uses the MRI apparatus. Is detected and the content of the abnormality is determined to be of high urgency, the workstation is powered on by the monitoring device. The conductive state, notifies the abnormal content from the communication unit to the via connection facilities network line.

  According to the present invention, when monitoring the state of the MRI apparatus, it is not necessary to always energize the power supply of the workstation having the communication unit. Therefore, the deterioration of the CPU and HDD of the workstation is reduced, and those A magnetic resonance imaging system and a monitoring method capable of reducing power consumption can be provided.

1 is an overall schematic diagram of an example of a magnetic resonance imaging system and a monitoring method according to the present invention. 3 is a flowchart for explaining the first embodiment. FIG. 6 is a diagram for explaining the second embodiment. 10 is a flowchart for explaining the second embodiment.

  Hereinafter, preferred embodiments of a magnetic resonance imaging system and a monitoring method of the present invention will be described in detail with reference to the accompanying drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiments of the invention, and the repetitive description thereof is omitted.

  An embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing an overall outline of an example of a magnetic resonance imaging system and a monitoring method according to the present invention. As shown in FIG. 1, the magnetic resonance imaging system includes a static magnetic field generator 102, a gradient magnetic field generator 103, an MRI apparatus 104, and a workstation 105.

  The static magnetic field generator 102 includes a high-frequency coil (transmitting coil) 106 and a high-frequency coil (receiving coil) 107. In the magnetic field method, a uniform static magnetic field is generated in the body axis direction, and a permanent magnet type, normal conduction type or superconducting type static magnetic field generation source is arranged around the subject 101. When the static magnetic field generation source is a superconducting system, a superconducting coil (not shown) is used as the static magnetic field generating coil. Liquid helium is used for cooling the superconducting coil, and a cooling device (not shown) using liquid helium is also included in the static magnetic field generator 102. A high-frequency coil (transmission coil) 106 is disposed in the vicinity of the subject 101 to cause nuclear magnetic resonance to occur in the nuclear spins of atoms constituting the biological tissue of the subject 101, and irradiates the subject 101 with RF pulses. A high-frequency coil (receiver coil) 107 is disposed in the vicinity of the subject 101 in order to detect an echo signal (NMR signal) emitted by nuclear magnetic resonance of nuclear spins constituting the biological tissue of the subject 101. Based on the detected NMR signal, an image reconstruction of the living tissue of the subject 101 is performed by the workstation 105.

  The gradient magnetic field generator 103 is a gradient magnetic field coil 108 that applies a gradient magnetic field in the three-axis directions of X, Y, and Z, which is the coordinate system (stationary coordinate system) of the MRI apparatus 104, and a gradient that drives each gradient magnetic field coil The magnetic field power source 109 is configured to drive the gradient magnetic field power source 109 of each coil, thereby applying gradient magnetic fields Gx, Gy, and Gz in the three axial directions of X, Y, and Z. At the time of imaging, a selective excitation gradient magnetic field pulse is applied in a direction orthogonal to the slice plane (imaging cross section) to set a slice plane for the subject 101, and in the remaining two directions orthogonal to the slice plane and orthogonal to each other A phase encoding direction gradient magnetic field pulse and a frequency encoding direction gradient magnetic field pulse are applied, and position information in each direction is encoded in the echo signal. The MRI apparatus 104 includes a static magnetic field generation apparatus 102, a gradient magnetic field generation apparatus 103, and a monitoring apparatus 110. The monitoring apparatus 110 includes a storage medium 121 that stores abnormal contents of the MRI apparatus 104 detected by the monitoring apparatus 110, and When a superconducting coil is used for the static magnetic field generating coil, the MAGNETIC CONTROL UNIT122 is used to monitor and control the superconducting coil temperature, internal pressure, and the remaining amount and temperature of liquid helium used for cooling the superconducting coil. And a cooling water monitoring device 123 for monitoring the temperature, flow rate, and pressure of the cooling water used in the MRI apparatus 104.

  The workstation 105 processes various data transmitted from the MRI apparatus 104, displays and saves the processing results, and inputs various control information of the MRI apparatus 104 to perform control. Further, the abnormality content of the MRI apparatus 104 transmitted from the monitoring apparatus 110 is reported to the related facility 120 via the network line 119, and the central processing unit (CPU) 111, the display 112, the HDD 113, the communication unit 114, A trackball or mouse 115, a keyboard 116, a workstation power supply 117, and a workstation power switch 118. The network line 119 includes an Internet line, a LAN, a telephone line, and the like. The related facility 120 includes a service center that performs maintenance of the MRI apparatus 104, a separate room in the same hospital where the MRI apparatus 104 is installed, and the like. When data from the MRI apparatus 104 is input to the CPU 111, the CPU 111 executes processing such as signal processing and image reconstruction, and displays the tomographic image of the subject 101 as a result on the display 112, and Save to HDD113 etc. In addition, various control information of the MRI apparatus 104 and control information of processes performed in various data processing are input using the trackball or the mouse 115 and the keyboard 116, and the operator can interactively observe the display 112 and the MRI apparatus 104. Control various processes.

  When an abnormality of the MRI apparatus 104 is detected by the monitoring device 110 and the abnormal content is notified to the workstation 105 from the monitoring device 110, the abnormal content is highly urgent and the workstation power supply If 117 is not energized, the monitoring device 110 uses the workstation power switch 118 to turn on the workstation power source 117, and from the communication unit 114 to the related facility 120 via the network line 119. Report the abnormality detected by 110. If the urgency of the abnormality content is low and the workstation power supply 117 is not energized, the monitoring device 110 stores the abnormality content in the storage medium 121, and then the workstation power supply 117 is energized. In this case, the abnormality content stored in the storage medium 121 by the monitoring device 110 is notified from the communication unit 114 to the related facility 120 via the network line 119. Whether the workstation power supply 117 is energized is determined by the monitoring device 110. In the energized state, a constant voltage of, for example, 3.3 (V) is output from the CPU 111 via the signal line 124 between the CPU 111 and the monitoring device 110. When the signal line 124 is not energized, the signal line 124 is set to GND by the resistor 125 arranged between the signal line 124 and GND.

  In FIG. 1, the high-frequency coil 106 and the gradient magnetic field coil 108 on the transmission side face the subject 101 in the static magnetic field space of the static magnetic field generator 102 in which the subject 101 is inserted, if the vertical magnetic field method is used. If the horizontal magnetic field method is used, the subject 101 is installed so as to surround it.

  The high-frequency coil 107 on the receiving side is installed so as to face or surround the subject 101. Currently, the radionuclide to be imaged by the magnetic resonance imaging apparatus is a hydrogen nucleus (proton) which is a main constituent material of the subject as widely used clinically. By imaging information on the spatial distribution of proton density and the spatial distribution of relaxation time in the excited state, the form or function of the human head, abdomen, limbs, etc. is imaged three-dimensionally.

Next, the operation of this embodiment will be described based on the flowchart of FIG.
First, in step S201, the monitoring device 110 receives the energization information of the workstation power supply 117 from the signal line 124.

  Next, in step S202, the monitoring apparatus 110 determines whether the workstation power supply 117 is in an energized state or not in an energized state. If the workstation power supply 117 is in the energized state, the process proceeds to step S209. If not, the process proceeds to step S203. Even when the process proceeds to step S203 and subsequent steps, if the workstation power supply 117 is energized by an operator or the like on the way, the process proceeds to step S209. However, this excludes the case where the workstation power supply 117 is energized in step S206 described later.

  Next, in step S203, the monitoring apparatus 110 monitors the MRI apparatus 104 for any abnormality. If there is an abnormality, the process proceeds to step S204, and if there is no abnormality, step S203 is repeated.

  Next, in step S204, the monitoring device 110 further determines the degree of urgency of the abnormal content for the content determined to be abnormal by the monitoring device 110. The determination of the degree of urgency is performed with, for example, two values of high and low. If the urgency level is high, the process proceeds to step S206, and if the urgency level is low, the process proceeds to step S205.

  Next, in step S205, the abnormality content determined to be less urgent by the monitoring device 110 is stored in the storage medium 121, and then stored in the storage medium 121 when the workstation power supply 117 is energized. The monitoring device 110 notifies the communication unit 114 of the abnormality content that is being performed, and the communication unit 114 notifies the related facility 120 of the abnormality content via the network line 119.

  Next, in step S206, the workstation power supply 117 is turned on by the monitoring device 110 using the workstation power switch 118.

  Next, in step S207, the abnormality content detected by the monitoring device 110 is notified to the communication unit 114 by the monitoring device 110, and further, the communication unit 114 reports the abnormality content to the related facility 120 via the network line 119. To do. In addition, when abnormality content is stored in the storage medium 121, the abnormality content stored may be reported to the related facility 120 via the network line 119 by the communication unit 114.

  Next, in step S208, the monitoring device 110 uses the workstation power switch 118 to release the energized state of the workstation power source 117. That is, the workstation power supply 117 is turned off.

  Next, in step S209, the monitoring device 110 determines whether the abnormal content is stored in the storage medium 121. If the abnormal content is stored, the process proceeds to step S210, and if the abnormal content is not stored, the step Proceed to S211.

  Next, in step S210, the monitoring device 110 notifies the communication unit 114 of the abnormal content stored in the storage medium 121, and the communication unit 114 further notifies the related facility 120 via the network line 119. Report the details of the abnormality.

  Next, in step S211, the monitoring apparatus 110 monitors the MRI apparatus 104 for any abnormality. If there is an abnormality, the process proceeds to step S212, and if there is no abnormality, step S211 is repeated.

  Next, in step S212, the abnormality content detected by the monitoring device 110 is notified to the communication unit 114 by the monitoring device 110, and the communication unit 114 notifies the related facility 120 of the abnormality content via the network line 119. .

  As described above, according to the magnetic resonance imaging system and the monitoring method of the present embodiment, even when the state of the MRI apparatus is constantly monitored, it is not necessary to always energize the workstation having the communication unit. It is possible to reduce the deterioration of the CPU 111 and the HDD 113 and further reduce their power consumption.

Next, the differences between the first embodiment and the first embodiment will be described with reference to FIG.
FIG. 3 is a diagram for explaining the second embodiment.
The magnetic resonance imaging system and monitoring method according to the present embodiment includes a communication apparatus 301 that notifies the related facility 120 of the abnormal content of the MRI apparatus 104. In the magnetic resonance imaging system and the monitoring method of the present embodiment, when the abnormality of the MRI apparatus 104 is detected by the monitoring apparatus 110 and the abnormality content is highly urgent, the communication apparatus power switch 303 is set by the monitoring apparatus 110. The communication device power supply 302 is energized and notified to the communication device 301 by the monitoring device 110, and the communication device 301 notifies the related facility 120 via the network line 119.

  If the abnormality content is low in urgency, the abnormality content is stored in the storage medium 121. The stored abnormality content is notified to the communication device 301 by the monitoring device 110 when the communication device 301 is energized next time, and the communication device 301 notifies the related facility 120 via the network line 119.

Next, the operation of this embodiment will be described with reference to the flowchart of FIG.
First, in step S401, the monitoring apparatus 110 monitors the MRI apparatus 104 for any abnormality. If there is an abnormality, the process proceeds to step S402, and if there is no abnormality, step S401 is repeated. Next, in step S402, the monitoring device 110 further determines the urgency of the abnormal content for the content determined to be abnormal by the monitoring device 110. The determination of the degree of urgency is performed with, for example, two values of high and low.

  If the urgency level is high, the process proceeds to step S404, and if the urgency level is low, the process proceeds to step S403. Next, in step S403, the abnormality content determined to be less urgent by the monitoring device 110 is stored in the storage medium 121, and then stored in the storage medium 121 when the communication device 301 is energized. The monitoring device 110 notifies the communication device 301 of the abnormal content, and the communication device 301 notifies the related facility 120 of the abnormal content via the network line 119.

  Next, in step S404, the communication device power supply 302 is energized by the monitoring device 110 using the communication device power switch 303. Next, in step S405, the abnormality content detected by the monitoring device 110 is notified to the communication device 301 by the monitoring device 110, and the communication device 301 reports the abnormality content to the related facility 120 via the network line 119. To do. In addition, when abnormality content is stored in the storage medium 121, the abnormality content stored may be reported to the related facility 120 via the network line 119 by the communication device 301.

  Next, in step S406, the monitoring device 110 releases the energized state of the communication device power supply 302 using the communication device power switch 303. That is, the communication device power supply 302 is turned off.

As described above, according to the magnetic resonance imaging system and the monitoring method of the present embodiment, even when the power supply for the workstation 118 is turned off, if an abnormality occurs in the MRI apparatus 104, the abnormality The contents can be reported to the related facility 120.
As mentioned above, although the Example of this invention was described, this invention is not limited to these.

  101 subject, 102 static magnetic field generator, 103 gradient magnetic field generator, 104 MRI apparatus, 105 workstation, 106 high-frequency coil (transmitting coil) on the transmitting side, 107 high-frequency coil (receiving coil) on the receiving side, 108 gradient magnetic field coil , 109 Gradient magnetic field power supply, 110 Monitoring device, 111 Central processing unit (CPU), 112 Display, 113 HDD, 114 Communication unit, 115 Trackball or mouse, 116 Keyboard, 117 Power supply for workstation, 118 Power switch for workstation, 119 Network line, 120 Related facilities, 121 Storage medium, 122 MAGNETIC CONTROL UNIT, 123 Cooling water monitoring device, 124 Signal line, 125 Resistance, 301 Communication device, 302 Communication device power supply, 303 Communication device power switch

Claims (8)

  A static magnetic field generator for generating a uniform static magnetic field in a space for accommodating a subject, a gradient magnetic field generator for generating a gradient magnetic field superimposed on the static magnetic field, and the static magnetic field generator or the gradient magnetic field generator An MRI apparatus including a monitoring apparatus that constantly monitors an abnormality of at least one of the apparatuses, and a workstation including a communication unit that reports an abnormality content detected by the monitoring apparatus to a related facility via a network line In the magnetic resonance imaging system, when the power supply of the workstation including the communication unit is not energized and the abnormality of the MRI apparatus is detected by the monitoring apparatus, the urgency of the abnormality content is determined by the monitoring apparatus And controlling the power supply of the workstation provided with the communication unit by the monitoring device according to the determination result. Magnetic resonance imaging systems with symptoms.   The magnetic resonance imaging system according to claim 1, further comprising: a storage medium for storing abnormal contents detected by the monitoring device.   The urgency level of the abnormality content is determined by the monitoring device with two levels of high and low, and when the urgency level of the abnormal content is high, the monitoring device causes the workstation including the communication unit to be energized, The magnetic resonance imaging system according to claim 2, wherein the abnormality content is notified from the monitoring device to the communication unit, and the abnormality content is reported from the communication unit to a related facility via a network line.   The urgency of the abnormality content is determined by the monitoring device with two levels of high and low, and when the urgency of the abnormality content is low and the power source of the workstation including the communication unit is not energized, the monitoring device When the abnormal content stored in the storage medium is stored in the storage medium, and the workstation including the communication unit is next energized, the abnormal content stored in the storage medium by the monitoring device is stored in the storage unit. 3. The magnetic resonance imaging system according to claim 2, wherein a notification is made to a related facility via a through network line.   A static magnetic field generator for generating a uniform static magnetic field in a space for accommodating a subject, a gradient magnetic field generator for generating a gradient magnetic field superimposed on the static magnetic field, and the static magnetic field generator or the gradient magnetic field generator A monitoring device that constantly monitors an abnormality of at least one of the devices, a communication device that notifies the related facility of the abnormality detected by the monitoring device using a network line, and a communication device that is a power source for the communication device In the MRI apparatus provided with a power supply, the monitoring device determines the urgency of the abnormality content with two levels of high and low, and when the determination result is high, the monitoring device supplies the communication device power supply to the energized state. The abnormality content is reported to a related facility via a network line through the communication device.   A static magnetic field generator for generating a uniform static magnetic field in a space for accommodating a subject, a gradient magnetic field generator for generating a gradient magnetic field superimposed on the static magnetic field, and the static magnetic field generator or the gradient magnetic field generator A monitoring device that constantly monitors the abnormality of at least one of the devices, an MRI apparatus that includes a storage medium for storing the abnormality content detected by the monitoring device, and the abnormality content detected by the monitoring device, In a magnetic resonance imaging system comprising a workstation provided with a communication unit for reporting to a related facility via a network line, the power supply state of the workstation is monitored by the monitoring device, and the power supply of the workstation is And when the abnormality of the MRI apparatus is detected by the monitoring device, Monitoring method for a magnetic resonance imaging system, characterized by determining the Kyudo a binary high and low.   When the urgency level of the abnormality content is high, the monitoring device causes the workstation including the communication unit to be energized, and the monitoring device notifies the communication unit of the abnormality content. The method of monitoring a magnetic resonance imaging system according to claim 6, wherein the abnormality content is reported to a related facility using a line.   When the urgency of the abnormal content is low, the monitoring device stores the abnormal content in the storage medium, and when the power supply of the workstation including the communication unit is next energized, the monitoring device 7. The method of monitoring a magnetic resonance imaging system according to claim 6, wherein the abnormality content stored in the storage medium is reported to a related facility through the communication unit and a network line.

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