JP2009050688A - Radiation image capturing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiation image capturing system capable of adjusting and controlling the exposure dose of radiation according to a subject when a radiation image is captured. <P>SOLUTION: A transmitter/receiver 48 of a radiation detecting cassette 24 receives subject ID information by means of the radio communication from an RFID tag 182. An ID collation part 160 collates the received subject ID information with subject ID information stored in an RFID memory 184, and when there is subject ID information matching the received information, the matching subject ID information is correlated with the radiation exposure dose stored in a dose storage part 186 and according to the matching subject ID information. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a radiographic imaging system having a radiation detection cassette that includes a radiation conversion panel that detects radiation transmitted through a subject and converts the detected radiation into radiation image information.

  2. Description of the Related Art In the medical field, radiation image capturing apparatuses that irradiate a subject with radiation and guide the radiation transmitted through the subject to a radiation conversion panel to capture a radiation image are widely used. In this case, the radiation conversion panel may be a conventional radiation film in which the radiation image is exposed and recorded, or radiation energy as the radiation image is accumulated in a phosphor, and the radiation image is irradiated with excitation light. A stimulable phosphor panel that can be extracted as stimulated emission light is known. These radiation conversion panels supply the radiation film on which the radiation image is recorded to the developing device to perform development processing, or supply the storage phosphor panel to the reading device to perform reading processing, The radiation image as a visible image is obtained.

  On the other hand, in an operating room or the like, it is necessary to be able to immediately read out and display a radiation image from a radiation conversion panel after imaging in order to perform a quick and accurate treatment on a patient. Radiation detection using a solid-state detector that converts radiation directly into electrical signals, or converts radiation into visible light with a scintillator and then converts it into electrical signals to read out as a radiation conversion panel that can meet such demands A vessel has been developed.

  By the way, in a radiographic imaging system using a radiation detection cassette that accommodates these radiation conversion panels, radiographic imaging and radiographic information management are performed using subject ID information for identifying a patient as a subject. (See Patent Documents 1 and 2).

  That is, in Patent Document 1, identification information related to radiographic image capturing including subject ID information is stored in advance in a storage unit in the radiation detection cassette, and identification information of a subject to be captured next is displayed every time a radiographic image is captured. It has been proposed that radiographic images can be efficiently captured by displaying them on an apparatus.

  Patent Document 2 proposes that subject ID information of an ID tag attached to a part of a patient's body is read by a portable medical terminal and the subject ID information is transmitted to a medical facility computer.

JP 2003-172783 A JP 2005-245828 A

  By the way, regarding the radiation irradiated to the radiation detection cassette from the radiation source through the subject at the time of capturing the radiation image, the radiation irradiation dose differs for each subject. That is, since there is an optimum radiation dose for each subject, the radiation dose needs to be managed or adjusted for each subject. However, in Patent Documents 1 and 2, since the radiation exposure dose is not managed for each subject, it is impossible to irradiate the subject with an appropriate radiation exposure dose when capturing a radiographic image.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a radiographic image capturing system capable of managing and adjusting the radiation dose of radiation at the time of capturing a radiographic image for each subject. And

The radiographic imaging system of the present invention is
A radiation source that outputs radiation;
A radiation detection cassette containing a radiation conversion panel for detecting the radiation transmitted through the subject and converting it into radiation image information;
An RFID tag arranged on the subject and storing subject ID information for identifying the subject;
An ID storage unit storing a plurality of subject ID information;
An ID verification unit;
A radiation dose storage unit in which a radiation dose corresponding to each subject ID information is stored;
Have
The radiation detection cassette further includes first wireless communication means,
The radiation source is accommodated in an imaging apparatus together with a second wireless communication unit capable of wireless communication with the first wireless communication unit,
The first wireless communication means receives the subject ID information from the RFID tag by wireless communication;
The ID collating unit collates each subject ID information stored in the ID storage unit and the received subject ID information, and if there is matching subject ID information, the matching subject ID information, The radiation exposure dose is stored in the radiation exposure dose storage unit and associated with the radiation exposure dose according to the matching subject ID information.

  According to the present invention, the first wireless communication unit receives the subject ID information from the RFID tag by wireless communication, and the ID collating unit stores the received subject ID information and the ID storage unit. If there is matching subject ID information by comparing each subject ID information, the radiation exposure corresponding to the matching subject ID information is stored in the radiation dose storage unit and matched with the subject ID information. Corresponds to the dose.

  Accordingly, the radiation exposure dose can be managed for each subject, and the radiation exposure dose of radiation at the time of capturing a radiographic image can be adjusted for each subject.

  As shown in FIG. 1, an operating table (bed) 16 on which a patient 14 lies is disposed in an operating room 12 in which a radiographic imaging system 10 according to the present embodiment is installed, and a doctor 18 uses it for an operation. An instrument table 20 on which various instruments to be placed is placed on the side of the operating table 16. Around the operating table 16, various devices necessary for the operation such as an anesthesia machine, an aspirator, an electrocardiograph, and a blood pressure monitor are arranged.

  The radiographic imaging system 10 includes an imaging device 22 for irradiating a patient 14 as a subject with radiation X having a dose (radiation irradiation dose) according to imaging conditions, and radiation detection for detecting the radiation X transmitted through the patient 14. A radiation detection cassette 24 having a built-in device (radiation conversion panel) 40 (see FIGS. 2 to 5), a display device 26 for displaying a radiation image based on the radiation X detected by the radiation detector 40, an imaging device 22, A radiation detection cassette 24 and a console (control device) 28 for controlling the display device 26 are provided. In addition, a wristband 180 including an RFID (Radio Frequency IDentification) tag 182 storing subject ID information for specifying the patient 14 is attached to the wrist of the patient 14 (see FIGS. 1 and 3). ). Note that signals are transmitted and received by radio communication using UWB (Ultra Wide Band) between the imaging device 22, the radiation detection cassette 24, the display device 26, and the console 28. Furthermore, the radiation detection cassette 24 and the RFID tag 182 In the meantime, signals are transmitted and received by wireless communication using UWB.

  The imaging device 22 is connected to the free arm 30 and can be moved to a desired position according to the imaging region of the patient 14 and can be retracted to a position that does not obstruct the operation by the doctor 18. Similarly, the display device 26 is connected to the free arm 32 and can be moved to a position where the doctor 18 can easily confirm the captured radiographic image.

  FIG. 2 is an internal configuration diagram of the radiation detection cassette 24. The radiation detection cassette 24 includes a casing (housing) 34 made of a material that transmits the radiation X. Inside the casing 34, a grid 38 for removing scattered radiation of the radiation X by the patient 14 from the irradiation surface 36 side of the casing 34 to which the radiation X is irradiated, and a radiation detector 40 for detecting the radiation X transmitted through the patient 14. And the lead plate 42 which absorbs the back scattered radiation of the radiation X is arrange | positioned in order. Note that the irradiation surface 36 of the casing 34 may be configured as a grid 38.

  The casing 34 includes a battery 44 that is a power source of the radiation detection cassette 24, a cassette control unit 46 that drives and controls the radiation detector 40 using electric power supplied from the battery 44, and detection by the radiation detector 40. A transmitter / receiver (first wireless communication means) 48 that transmits and receives a signal including information on the radiation X to and from the console 28 is accommodated. The cassette controller 46 and the transmitter / receiver 48 are preferably provided with a lead plate or the like on the irradiation surface 36 side of the casing 34 in order to avoid damage due to irradiation with the radiation X.

  FIG. 3 is a side view of the imaging device 22, the radiation detection cassette 24, and the operating table 16. The transceiver 48 of the radiation detection cassette 24 can receive subject ID information of the patient 14 stored in the RFID tag 182 from the RFID tag 182 by wireless communication. The transceiver 48 can transmit and receive signals by wireless communication with a transceiver (second wireless communication means) 76 in the photographing apparatus 22.

  FIG. 4 is a circuit configuration block diagram of the radiation detector 40. The radiation detector 40 has a photoelectric conversion layer 51 made of a material such as amorphous selenium (a-Se) that senses the radiation X and generates charges on an array of thin film transistor (TFT) 52. After the generated charge is stored in the storage capacitor 53, the TFT 52 is sequentially turned on for each row, and the charge is read as an image signal. In FIG. 4, only the connection relationship between one pixel 50 including the photoelectric conversion layer 51 and the storage capacitor 53 and one TFT 52 is shown, and the configuration of the other pixels 50 is omitted. Amorphous selenium must be used within a predetermined temperature range because its structure changes and its function decreases at high temperatures. Therefore, it is preferable to provide means for cooling the radiation detector 40 in the radiation detection cassette 24.

  A gate line 54 extending parallel to the row direction and a signal line 56 extending parallel to the column direction are connected to the TFT 52 connected to each pixel 50. Each gate line 54 is connected to a line scanning drive unit 58, and each signal line 56 is connected to a multiplexer 66 constituting a reading circuit. Control signals Von and Voff for controlling on / off of the TFTs 52 arranged in the row direction are supplied from the line scanning drive unit 58 to the gate line 54. In this case, the line scan driving unit 58 includes a plurality of switches SW1 for switching the gate lines 54 and an address decoder 60 for outputting a selection signal for selecting one of the switches SW1. An address signal is supplied from the cassette control unit 46 to the address decoder 60.

  In addition, the charge held in the storage capacitor 53 of each pixel 50 flows out to the signal line 56 through the TFTs 52 arranged in the column direction. This charge is amplified by the amplifier 62. A multiplexer 66 is connected to the amplifier 62 via a sample and hold circuit 64. The multiplexer 66 includes a plurality of switches SW2 for switching the signal line 56, and an address decoder 68 for outputting a selection signal for selecting one of the switches SW2. An address signal is supplied from the cassette control unit 46 to the address decoder 68. An A / D converter 70 is connected to the multiplexer 66, and radiation image information converted into a digital signal by the A / D converter 70 is supplied to the cassette control unit 46.

  FIG. 5 is a configuration block diagram of the radiation image capturing system 10 including the imaging device 22, the radiation detection cassette 24, the display device 26, the console 28, and the RFID tag 182. The console 28 is connected to a radiology information system (RIS) 29 for comprehensively managing radiographic image information and other information handled in the radiology department in the hospital. A medical information system (HIS) 31 for comprehensively managing information is connected.

  The imaging device 22 includes an imaging switch 72, a radiation source 74, a transceiver 76, and a radiation source controller 78.

  The transceiver 76 receives a shooting condition from the console 28 by wireless communication, and transmits a shooting completion signal by wireless communication to the console 28. Further, as described above, the transmitter / receiver 76 can perform wireless communication with the transmitter / receiver 48 of the radiation detection cassette 24.

  The radiation source control unit 78 controls the radiation source 74 based on the imaging start signal supplied from the imaging switch 72 and the imaging conditions supplied from the transceiver 76. The radiation source 74 outputs the radiation X based on the control from the radiation source control unit 78.

  On the other hand, the cassette control unit 46 of the radiation detection cassette 24 includes an address signal generation unit 80, an image memory 82, a cassette ID memory 84, an ID collation unit 160, an RFID memory (ID storage unit) 184, and a dose storage unit. (Radiation irradiation dose storage unit) 186.

  The address signal generator 80 supplies an address signal to the address decoder 60 of the line scan driver 58 and the address decoder 68 of the multiplexer 66 that constitute the radiation detector 40. The image memory 82 stores the radiation image information detected by the radiation detector 40. The cassette ID memory 84 stores cassette ID information for specifying the radiation detection cassette 24. The transceiver 48 receives a transmission request signal from the console 28 by wireless communication, and wirelessly communicates the cassette ID information stored in the cassette ID memory 84 and the radiation image information stored in the image memory 82 to the console 28. Send by.

  The RFID memory 184 stores subject ID information of a plurality of patients 14. In the dose storage unit 186, the optimum radiation dose of the radiation X irradiated to the patient 14 at the time of taking a radiation image is stored for each patient 14 (each subject).

  The ID collation unit 160 collates the subject ID information received by the transceiver 48 with each subject ID information stored in the RFID memory 184, and if there is matching subject ID information, the matching subject ID information. The radiation exposure dose corresponding to is read out from the dose storage unit 186. In this case, the ID collation unit 160 regards the read radiation exposure dose as the optimal radiation exposure dose of the radiation X irradiated to the patient 14 with the matching subject ID information at the time of capturing a radiographic image. The matched subject ID information and the read radiation exposure dose are associated with each other and transmitted from the transceiver 48 to the transceiver (third wireless communication means) 96 of the console 28 by wireless communication.

  The display device 26 includes a receiver 90 that receives radiation image information from the console 28, a display control unit 92 that performs display control of the received radiation image information, and a display that displays the radiation image information processed by the display control unit 92. Part 94.

  The console 28 includes a transmitter / receiver 96, an imaging condition management unit (control radiation dose storage unit) 98, an image processing unit (image processing means) 100, an image memory 101, a patient information management unit 102, and cassette information. The management unit 104, an ID verification unit (control ID verification unit) 162, and an RFID memory (control ID storage unit) 188 are provided.

  The transmitter / receiver 96 transmits / receives necessary information including radiographic image information to / from the imaging device 22, the radiation detection cassette 24, and the display device 26 by wireless communication. The shooting condition management unit 98 manages shooting conditions necessary for shooting by the shooting device 22. The image processing unit 100 performs image processing on the radiation image information transmitted from the radiation detection cassette 24. An image memory 101 stores the radiation image information subjected to the image processing. The patient information management unit 102 manages patient information of the patient 14 to be imaged. The cassette information management unit 104 manages the cassette ID information transmitted from the radiation detection cassette 24.

  Similar to the RFID memory 184 in the radiation detection cassette 24, subject ID information of a plurality of patients 14 is stored in the RFID memory 188. The ID collating unit 162 collates the subject ID information received by the transceiver 96 with each subject ID information stored in the RFID memory 188. In this case, if the ID collating unit 162 determines that there is matching subject ID information, the console 28 determines the radiation exposure dose based on the radiation exposure dose received by the transmitter / receiver 96 together with the matching subject ID information. The imaging condition management unit 98 stores (registers) the imaging conditions corresponding to the above. In the imaging condition management unit 98, if imaging conditions have already been registered for the patient 14 with the matching subject ID information, the console 28 displays the imaging conditions registered in the imaging condition management unit 98 as described above. Update the imaging conditions according to the radiation dose.

  Further, the console 28 may be installed outside the operating room 12 as long as it can transmit and receive signals to and from the imaging device 22, the radiation detection cassette 24, and the display device 26 by wireless communication.

  The imaging conditions are conditions for determining a tube voltage, a tube current, an irradiation time, and the like for irradiating the imaging region of the patient 14 with radiation X having an appropriate radiation irradiation dose. Conditions such as an imaging region and an imaging method can be given. The patient information is information for identifying the patient 14 such as the name, sex, and patient ID number of the patient 14. The imaging ordering information including these imaging conditions and patient information can be set directly on the console 28 or supplied from the outside to the console 28 via the RIS 29. In the radiographic imaging system 10, the RFID tag Due to the transmission of subject ID information from the radiation detection cassette 24 to the radiation detection cassette 24, the imaging condition management unit 98 registers (stores) the imaging conditions based on the radiation exposure dose transmitted from the radiation detection cassette 24 to the console 28. I am doing so.

  The radiographic image capturing system 10 according to the present embodiment is basically configured as described above, and the operation thereof will be described next.

  The radiographic image capturing system 10 is installed in the operating room 12 and is used, for example, when a radiographic image needs to be captured during surgery of the patient 14 by the doctor 18. Therefore, the patient information of the patient 14 to be imaged is registered in advance in the patient information management unit 102 of the console 28 prior to imaging. In addition, when the radiation irradiation dose, imaging region, and imaging method are determined in advance, these imaging conditions are registered in the imaging condition management unit 98 in advance. In the state where the above preparatory work is completed, the operation for the patient 14 is performed.

  When radiographing is performed during surgery, the doctor 18 or a radiographer in charge takes the radiation detection cassette 24 at a predetermined position between the patient 14 and the operating table 16 with the irradiation surface 36 facing the imaging device 22 side. Is installed. Next, after appropriately moving the imaging device 22 to a position facing the radiation detection cassette 24, the imaging switch 72 is operated to perform imaging.

  FIG. 6 illustrates the operation of the radiographic imaging system 10 from transmission of subject ID information from the RFID tag 182 to the radiation detection cassette 24 (step S1) to irradiation of the patient 14 with radiation X (step S13). It is a flowchart for.

  In step S1, when the doctor 18 or the radiologist in charge installs the radiation detection cassette 24 at a predetermined position between the patient 14 and the operating table 16 with the irradiation surface 36 facing the imaging apparatus 22, the RFID 18 The tag 182 transmits its own subject ID information. When the transceiver 48 of the radiation detection cassette 24 receives the subject ID information (step S2), the ID verification unit 160 receives the subject ID received by the transceiver 48. The information is compared with each subject ID information stored in the RFID memory 184 to determine whether there is matching subject ID information (step S3).

  When it is determined in step S3 that there is matching subject ID information, the ID collation unit 160 reads out the radiation dose corresponding to the matching subject ID information from the dose storage unit 186, and the matching subject ID information The read radiation exposure dose is associated and transmitted from the transceiver 48 to the transceiver 96 by wireless communication (step S4).

  If the ID collation unit 160 determines in step S3 that there is no matching subject ID information, the radiation detection cassette 24 does not perform the processes in and after step S4, and re-executes the process in step S2.

  In step S 5, when the transceiver 96 of the console 28 receives the associated subject ID information and radiation dose, the ID collation unit 162 stores the subject ID information received by the transceiver 96 and the RFID memory 188. Each subject ID information is collated, and it is determined whether there is matching subject ID information (step S6).

  In step S6, when the ID collation unit 162 determines that there is matching subject ID information, the console 28 takes an imaging condition based on the radiation irradiation dose received by the transceiver 96 together with the matching subject ID information. The condition management unit 98 stores (updates) (step S7).

  In step S6, when the ID collation unit 162 determines that there is no matching subject ID information, the console 28 does not perform the processes in and after step S7, and re-executes the process in step S5.

  Next, when the doctor 18 or the radiographer operates the imaging switch 72 (see FIG. 5) in step S8, the radiation source controller 78 of the imaging apparatus 22 performs imaging on the console 28 via the transceivers 76 and 96. Request transmission of conditions (step S9).

  The console 28 receives the request in step S10, and then transmits the imaging conditions relating to the imaging region of the patient 14 registered in the imaging condition management unit 98 to the imaging apparatus 22 via the transceivers 96 and 76. (Step S11). When receiving the imaging condition in step S12, the radiation source control unit 78 controls the radiation source 74 in accordance with the imaging condition, so that the radiation X having a predetermined radiation irradiation dose (radiation irradiation dose according to the subject ID information) is generated. The patient 14 is irradiated (step S13).

  In step S13 and subsequent steps, the radiation X transmitted through the patient 14 is irradiated with the radiation detector 40 after the scattered radiation is removed by the grid 38 of the radiation detection cassette 24, and each pixel 50 constituting the radiation detector 40 is used. Is converted into an electric signal by the photoelectric conversion layer 51, and held as a charge in the storage capacitor 53 (see FIG. 4). Next, the charge information which is the radiographic image information of the patient 14 held in each storage capacitor 53 is in accordance with the address signal supplied from the address signal generation unit 80 constituting the cassette control unit 46 to the line scanning drive unit 58 and the multiplexer 66. Read out.

  That is, the address decoder 60 of the line scan driver 58 outputs a selection signal according to the address signal supplied from the address signal generator 80, selects one of the switches SW1, and the TFT 52 connected to the corresponding gate line 54. A control signal Von is supplied to the gates of the two. On the other hand, the address decoder 68 of the multiplexer 66 outputs a selection signal in accordance with the address signal supplied from the address signal generation unit 80, sequentially switches the switch SW2, and is connected to the gate line 54 selected by the line scan driving unit 58. Radiation image information, which is charge information held in the storage capacitor 53 of each pixel 50, is sequentially read out via the signal line 56.

  The radiation image information read from the storage capacitor 53 of each pixel 50 connected to the selected gate line 54 of the radiation detector 40 is amplified by each amplifier 62 and then sampled by each sample and hold circuit 64. The signal is supplied to the A / D converter 70 via the multiplexer 66 and converted into a digital signal. The radiographic image information converted into the digital signal is temporarily stored in the image memory 82 of the cassette control unit 46.

  Similarly, the address decoder 60 of the line scan driving unit 58 sequentially switches the switch SW1 in accordance with the address signal supplied from the address signal generating unit 80, and the storage capacitor 53 of each pixel 50 connected to each gate line 54. The stored radiation image information, which is charge information, is read through the signal line 56 and stored in the image memory 82 of the cassette control unit 46 through the multiplexer 66 and the A / D converter 70.

  The radiation image information stored in the image memory 82 is transmitted to the console 28 by wireless communication via the transceiver 48.

  The radiographic image information transmitted to the console 28 is received by the transmitter / receiver 96, subjected to predetermined image processing in the image processing unit 100, and then associated with the patient information of the patient 14 registered in the patient information management unit 102. Stored in the image memory 101.

  The radiographic image information subjected to the image processing is transmitted from the transceiver 96 to the display device 26. The display device 26 that has received the radiation image information by the receiver 90 controls the display unit 94 by the display control unit 92 to display the radiation image. The doctor 18 performs the operation while confirming the radiation image displayed on the display unit 94.

  Thus, according to the radiographic imaging system 10 according to the present exemplary embodiment, the transceiver 48 of the radiation detection cassette 24 receives subject ID information from the RFID tag 182 by wireless communication, and the ID verification unit 160 receives the subject ID information. The subject ID information and each subject ID information stored in the RFID memory 184 are collated, and if there is matching subject ID information, the matching subject ID information is stored in the dose storage unit 186 and matches the subject ID information. The radiation dose corresponding to the subject ID information is associated.

  Thereby, it becomes possible to manage the radiation exposure dose for each patient 14, and the radiation exposure dose of the radiation X at the time of capturing a radiographic image can be adjusted for each patient 14.

  The transceiver 48 transmits the associated subject ID information and radiation dose to the transceiver 96 of the console 28 by wireless communication, and the ID verification unit 162 of the console 28 receives the received subject ID information and the RFID Each subject ID information stored in the memory 188 is collated, and if there is matching subject ID information, the imaging condition management unit 98 stores the imaging conditions according to the radiation irradiation dose received together with the matching subject ID information. (Update). This makes it possible to easily and accurately manage the radiation dose (imaging conditions) for the patient 14 with the matching subject ID information on the console 28.

  Furthermore, the console 28 transmits the imaging conditions stored in the imaging condition management unit 98 to the imaging device 22 when a transmission request for the imaging conditions of the patient 14 is received from the imaging device 22, so that the radiographic image is captured. Thus, it becomes possible to irradiate the patient 14 with the radiation X having the optimum radiation irradiation dose.

  Furthermore, between the radiation detection cassette 24 and the console 28, between the radiation detection cassette 24 and the imaging device 22, between the imaging device 22 and the console 28, between the console 28 and the display device 26, and the radiation detection cassette 24. And the RFID tag 182 transmit and receive signals by UWB wireless communication. That is, since the cable for transmitting and receiving the signal is not connected between the imaging device 22, the radiation detection cassette 24, the display device 26, the console 28, and the RFID tag 182, for example, these are placed on the floor surface of the operating room 12. The cable is not arranged, and there is no possibility of hindering the work of the doctor 18 or the like. Therefore, the doctor 18 can perform his / her work efficiently. In addition, by using UWB as the wireless communication, it is possible to reduce power consumption, improve fading resistance, and improve high-speed communication compared to conventional wireless communication.

  In the radiographic imaging system 10 according to the present embodiment, the subject ID information and the radiation irradiation dose are transmitted from the transceiver 48 to the transceiver 96 by wireless communication, but instead of this, transmission / reception from the transceiver 48 is performed. The data may be transmitted (transferred) to the transmitter / receiver 96 via the device 76 by wireless communication.

  In the radiographic imaging system 10 according to the present embodiment, as described above, the ID collation unit 160 includes the subject ID information received by the transceiver 48 and the subject ID information stored in the RFID memory 184. If they match, the matching subject ID information is associated with the radiation exposure dose stored in the dose storage unit 186. Of course, even if this is changed as in the following (1) or (2), the effect of the present embodiment described above can be obtained.

  (1) The imaging condition management unit 98 stores in advance the imaging conditions including the radiation dose corresponding to the patient 14 in the subject ID information for each patient 14 (for each subject). The transceiver 48 transmits the received subject ID information to the transceiver 96. The ID collating unit 162 collates the subject ID information received by the transmitter / receiver 96 with each subject ID information stored in the RFID memory 188, and if there is matching subject ID information, the matching subject The ID information is associated with the radiation exposure dose (imaging condition) in the imaging condition management unit 98 corresponding to the subject ID information.

  (2) The ID collation unit 160 collates the subject ID information received by the transmitter / receiver 48 with each subject ID information stored in the RFID memory 184. The subject ID information to be transmitted is transmitted from the transmitter / receiver 48 to the transmitter / receiver 96 by wireless communication, and the matching subject ID information and the radiation exposure dose (imaging condition) in the imaging condition management unit 98 corresponding to the subject ID information are obtained. Associate.

  In the radiographic imaging system 10 according to the present embodiment, radiographic images are captured due to the operation of the imaging switch 72 of the doctor 18 or the radiographer. However, the operation of the console 28 by the doctor 18 or the radiographer is performed. As a result, a radiographic image may be taken.

  Furthermore, in the radiographic imaging system 10 according to the present embodiment, for example, the radiation detector 40 accommodated in the radiation detection cassette 24 converts the dose of the incident radiation X directly into an electrical signal by the photoelectric conversion layer 51. However, instead of this, the incident radiation X is once converted into visible light by a scintillator, and then this visible light is converted into an electrical signal using a solid-state detection element such as amorphous silicon (a-Si). A radiation detector may be used (see Japanese Patent No. 3494683).

  Also, radiation image information can be obtained using a light conversion type radiation detector. In this light conversion type radiation detector, when radiation is incident on each solid detection element arranged in a matrix, an electrostatic latent image corresponding to the dose is accumulated and recorded in the solid detection element. When reading the electrostatic latent image, the radiation detector is irradiated with reading light, and the value of the generated current is acquired as radiation image information. The radiation detector can erase and reuse the radiation image information that is the remaining electrostatic latent image by irradiating the radiation detector with erasing light (see Japanese Patent Application Laid-Open No. 2000-105297). .

  Furthermore, when the radiation detection cassette 24 is used in the operating room 12 or the like, there is a possibility that blood or other germs may adhere. Therefore, the radiation detection cassette 24 has a waterproof and airtight structure and is sterilized and washed as necessary, so that one radiation detection cassette 24 can be used repeatedly.

  Furthermore, the radiation detection cassette 24 is not limited to being used in the operating room 12, and can be applied to, for example, medical examinations and rounds in hospitals.

  Further, the wireless communication between the radiation detection cassette 24 and the external device may be performed by optical wireless communication using infrared rays or the like instead of normal communication using radio waves.

  Furthermore, it is more preferable to configure the radiation detection cassette 500 as shown in FIG.

  That is, in the radiation detection cassette 500, the guide line 504 serving as a reference for the imaging region and the imaging position is formed on the radiation irradiation surface side of the casing 502. Using this guide line 504, the subject (patient 14) is positioned with respect to the radiation detection cassette 500, and the radiation image information can be recorded in an appropriate imaging region by setting the radiation X irradiation range. .

  A display unit 506 for displaying various types of information related to the radiation detection cassette 500 is disposed in a portion outside the imaging region of the radiation detection cassette 500. The display unit 506 displays the ID information of the patient 14 recorded in the radiation detection cassette 500, the number of times the radiation detection cassette 500 is used, the cumulative exposure dose, and the state of charge of the battery 44 built in the radiation detection cassette 500 (remaining amount). Capacity), radiographic image information imaging conditions, positioning image of the patient 14 with respect to the radiation detection cassette 500, and the like are displayed. In this case, for example, the radiologist confirms the patient 14 according to the ID information displayed on the display unit 506, confirms in advance that the radiation detection cassette 500 is in a usable state, and displays the displayed positioning image. Based on the above, it is possible to position the desired imaging region of the patient 14 in the radiation detection cassette 500 and to perform imaging of optimal radiation image information.

  In addition, by forming the handle portion 508 in the radiation detection cassette 500, the radiation detection cassette 500 can be easily handled and carried.

  On the side of the radiation detection cassette 500, an AC adapter input terminal 510, a USB (Universal Serial Bus) terminal 512, and a card slot 516 for loading a memory card 514 are preferably provided.

  The input terminal 510 is connected to an AC adapter when the charging function of the battery 44 built in the radiation detection cassette 500 is deteriorated or when sufficient time cannot be secured for charging the battery 44. The radiation detection cassette 500 can be immediately put into a usable state by supplying power from.

  The USB terminal 512 or the card slot 516 can be used when the radiation detection cassette 500 cannot transmit and receive information by wireless communication with an external device such as the console 28. In other words, by connecting a cable to the USB terminal 512, information can be transmitted / received to / from an external device by wired communication. In addition, information can be transmitted and received by loading a memory card 514 into the card slot 516, recording necessary information on the memory card 514, and then removing the memory card 514 and loading it into an external device.

  As shown in FIG. 8, it is preferable to place a cradle 518 that is loaded with a radiation detection cassette 24 and charges a built-in battery 44 at a required location in the operating room 12 or hospital. In this case, the cradle 518 transmits and receives necessary information to and from external devices such as the RIS 29, the HIS 31, and the console 28 using not only the charging of the battery 44 but also the wireless communication function or the wired communication function of the cradle 518. You may do it. The information to be transmitted and received can include radiation image information recorded in the radiation detection cassette 24 loaded in the cradle 518.

  In addition, a display unit 520 is provided in the cradle 518, and necessary information including the charged state of the loaded radiation detection cassette 24 and the radiation image information acquired from the radiation detection cassette 24 is displayed on the display unit 520. You may make it display.

  In addition, a plurality of cradle 518 is connected to the network, the charging state of the radiation detection cassette 24 loaded in each cradle 518 is collected via the network, and the location of the radiation detection cassette 24 in a usable charging state is confirmed. It can also be configured to be able to.

  Of course, the radiographic imaging system according to the present invention is not limited to the above-described embodiments, and various configurations can be adopted without departing from the gist of the present invention.

It is explanatory drawing of the operating room where the radiographic imaging system of this embodiment was installed. It is an internal block diagram of the radiation detection cassette of FIG. It is a side view of the imaging device of FIG. 1, a radiation detection cassette, and an operating table. It is a circuit block diagram of the radiation detector of FIG. FIG. 2 is a configuration block diagram of the radiographic image capturing system in FIG. 1. It is a flowchart for demonstrating operation | movement of the radiographic imaging system from transmission of the subject ID information from the RFID tag to radiation irradiation. It is another block diagram of a radiation detection cassette. It is a block diagram of the cradle which charges a radiation detection cassette.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Radiographic imaging system 12 ... Operating room 14 ... Patient 16 ... Operating table 22 ... Imaging device 24, 500 ... Radiation detection cassette 26 ... Display device 28 ... Console 29 ... RIS
31 ... HIS
40 ... Radiation detector 44 ... Battery 46 ... Cassette control unit 48, 76, 96 ... Transmitter / receiver 50 ... Pixel 74 ... Radiation source 82, 101 ... Image memory 84 ... Cassette ID memory 90 ... Receiver 94 ... Display unit 98 ... Imaging Condition management unit 100 ... Image processing unit 102 ... Patient information management unit 104 ... Cassette information management unit 160, 162 ... ID collation unit 182 ... RFID tags 184, 188 ... RFID memory 186 ... Dose storage unit

Claims (16)

A radiation source that outputs radiation;
A radiation detection cassette containing a radiation conversion panel for detecting the radiation transmitted through the subject and converting it into radiation image information;
An RFID tag arranged on the subject and storing subject ID information for identifying the subject;
An ID storage unit storing a plurality of subject ID information;
An ID verification unit;
A radiation dose storage unit in which a radiation dose corresponding to each subject ID information is stored;
Have
The radiation detection cassette further includes first wireless communication means,
The radiation source is accommodated in an imaging apparatus together with a second wireless communication unit capable of wireless communication with the first wireless communication unit,
The first wireless communication means receives the subject ID information from the RFID tag by wireless communication;
The ID collating unit collates each subject ID information stored in the ID storage unit and the received subject ID information, and if there is matching subject ID information, the matching subject ID information, A radiographic imaging system characterized by associating radiation exposure doses stored in the radiation exposure dose storage unit and corresponding to the matching subject ID information. The system of claim 1, wherein
A control device that controls the imaging device and the radiation detection cassette, and further includes a third wireless communication unit;
The radiation image capturing system, wherein the ID storage unit, the ID collation unit, and the radiation exposure dose storage unit are arranged in the radiation detection cassette and / or the control device. The system of claim 2, wherein
When the ID storage unit, the ID collation unit, and the radiation exposure dose storage unit are arranged in the radiation detection cassette, the first wireless communication unit wirelessly communicates the associated subject ID information and radiation exposure dose. And transmitting to the third wireless communication means. The system of claim 2, wherein
When the ID storage unit, the ID collation unit and the radiation dose storage unit are arranged in the control device,
The first wireless communication means transmits the subject ID information received from the RFID tag to the third wireless communication means by wireless communication,
The ID collating unit collates the subject ID information received by the third wireless communication unit with each subject ID information stored in the ID storage unit. The system of claim 2, wherein
When the ID storage unit and the ID collation unit are arranged in the radiation detection cassette, and the radiation dose storage unit is arranged in the control device,
The ID collation unit collates each subject ID information stored in the ID storage unit with the received subject ID information, and if there is matching subject ID information, the matching subject ID information Radiation irradiation according to the matched subject ID information stored in the radiation exposure dose storage unit and the matched subject ID information transmitted from the first wireless communication unit to the third wireless communication unit by wireless communication A radiographic imaging system characterized by associating doses. The system according to any one of claims 2 to 5,
The first to third wireless communication means can wirelessly communicate with each other, and the wireless communication by the first to third wireless communication means is wireless communication using UWB. The system of claim 2, wherein
The radiation detection cassette includes the ID storage unit, the ID collation unit, and the radiation dose storage unit, and the control device stores a plurality of subject ID information, a control ID collation unit, A control radiation dose storage unit is arranged,
The control ID collating unit collates the subject ID information received by the third wireless communication means with each subject ID information stored in the control ID storage unit, and if there is a matching subject ID information. For example, the radiographic imaging system characterized in that the radiation dose received by the third wireless communication means is stored in the control radiation dose storage unit. The system of claim 7, wherein
When the control device receives a transmission request for imaging conditions of the subject from the imaging device, the control device transmits the imaging conditions including the radiation exposure dose stored in the control radiation exposure dose storage unit to the imaging device. A radiographic imaging system characterized by: The system according to any one of claims 2 to 8,
The first radio communication unit transmits the radiographic image information converted by the radiation conversion panel to the third radio communication unit by radio communication. The system of claim 1, wherein
A control device for controlling the imaging device and the radiation detection cassette;
The first wireless communication means transmits the associated subject ID information and radiation dose to the second wireless communication means by wireless communication,
The radiographic imaging system, wherein the radiographing apparatus transfers the associated subject ID information and radiation dose received by the second wireless communication unit to the control apparatus. The system of claim 10, wherein
The radiation detection cassette includes the ID storage unit, the ID collation unit, and the radiation dose storage unit, and the control device stores a plurality of subject ID information, a control ID collation unit, A control radiation dose storage unit is arranged,
The control ID collating unit collates the subject ID information transferred from the photographing device to the control device and each subject ID information stored in the control ID storage unit, and the matching subject ID information is found. If there is, the radiation image capturing system, wherein the radiation dose transferred to the control device is stored in the control radiation dose storage unit. The system according to any one of claims 1 to 11,
The radiographic imaging system, wherein the wireless communication between the first wireless communication means and the RFID tag is wireless communication using UWB. The system according to any one of claims 1 to 12,
The radiation image capturing system, wherein the radiation conversion panel acquires the radiation image information by directly converting the radiation into an electrical signal. The system of claim 1, wherein
The radiation conversion panel, the ID storage unit, the ID collation unit, the radiation irradiation dose storage unit, and the first wireless communication unit are housed in a substantially rectangular housing,
The said housing | casing consists of the material which permeate | transmits the said radiation, The radiographic imaging system characterized by the above-mentioned. The system according to any one of claims 1 to 14,
A display device;
A radiographic imaging system in which UWB wireless communication is performed between the control device and the display device. The system according to any one of claims 1 to 15,
A radiographic imaging system, wherein a wristband including the RFID tag is attached to a patient's wrist as the subject.

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