JP2010071726A - Radiation detecting device and system of photographing radiation image - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiation detecting device that can acquire information about a highly precise radiation image by surely shading a radiation conversion panel from ambient light, and a system of photographing a radiation image. <P>SOLUTION: In the radiation detecting device 10A, a cassette storage bag 13A is made of a material that blocks ambient light and passes a radiation beam 14. A radiation detecting cassette 15A is stored in the cassette storage bag 13A. A rod type antenna 32 is projected to the outside so as to penetrate through an electric insulation member 30 provided on a lid section 28d of the cassette storage bag 13A from the radiation detecting cassette 15A. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a radiation detection apparatus including a radiation conversion panel that detects radiation transmitted through a subject and converts the detected radiation into radiation image information, and a radiation image capturing system including the radiation detection apparatus.

  2. Description of the Related Art In the medical field, a radiation image capturing system is widely used that irradiates a subject with radiation and guides the radiation transmitted through the subject to a radiation conversion panel to capture radiation image information. As the radiation conversion panel, the radiation image information is obtained by storing radiation energy as the radiation image information on a conventional radiation film in which the radiation image information is exposed and recorded, and irradiating 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 information is recorded to a developing device for development processing, or supply the storage phosphor panel to a reading device for reading processing. A visible image can be obtained.

  On the other hand, in an operating room or the like, it is necessary to be able to immediately read out and display radiation image information 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 and reads it as a radiation conversion panel that can meet such demands A vessel has been developed.

  Patent Document 1 includes a scintillator that converts radiation transmitted through a subject into visible light, and a solid-state detection element that converts the visible light into an electrical signal (radiation image information), and has a flexible radiation detection. It has been proposed to store the vessel (radiation conversion panel) in a flexible case.

JP 2003-70776 A

  By the way, when external light is incident on a radiation conversion panel including a scintillator, the solid state detection element converts visible light converted from radiation in the scintillator and the external light into an electrical signal. The signal component corresponding to the external light becomes noise of radiation image information. Therefore, in order to remove the noise, it is desirable that the radiation conversion panel can be shielded from the external light. However, Patent Document 1 does not propose any shielding of the external light.

  The present invention has been made in view of the above problems, and a radiation detection apparatus and a radiation image capturing system capable of acquiring radiation image information with high accuracy by reliably shielding a radiation conversion panel from external light. The purpose is to provide.

  The present invention provides a radiation detection apparatus, a radiation conversion panel having a scintillator that converts radiation that has passed through a subject into visible light, a solid-state detection element that converts the visible light into an electrical signal, and an external housing for housing the radiation conversion panel. And a storage body that blocks light and transmits the radiation.

  According to the present invention, the storage body that stores the radiation conversion panel shields the external light and transmits the radiation, so that the radiation conversion panel can be surely shielded from the external light. It is possible to acquire the radiation image information.

  A radiation detection apparatus 10A according to a first embodiment of the present invention and a radiation image capturing system 12A including the radiation detection apparatus 10A will be described with reference to FIGS.

  As shown in FIG. 1, the radiographic imaging system 12 </ b> A has a radiation source 16 for irradiating a patient 18 as a subject with a radiation 14 having a dose according to imaging conditions, and can transmit the radiation 14 and external light. A cassette storage bag (storage body) 13A capable of shielding light, a radiation detection cassette 15A including a radiation detector (radiation conversion panel) 40 for detecting the radiation 14 stored in the cassette storage bag 13A and transmitted through the patient 18, and radiation. A display device 22 that displays radiation image information based on the radiation 14 detected by the detector 40, and a console (control device) 20 that controls the radiation detection device 10 </ b> A, the radiation source 16, and the display device 22 are provided. Between the console 20 and the radiation detection device 10A, the radiation source 16, and the display device 22, for example, UWB (Ultra Wide Band), IEEE802.11. Signal transmission / reception is performed by wireless communication using a wireless LAN (Local Area Network) such as a / g / n or millimeter waves. The console 20 is connected to a radiology information system (RIS) 24 that comprehensively manages radiographic image information and other information handled in the radiology department in the hospital, and the RIS 24 is connected to medical information in the hospital. A medical information system (HIS) 26 for comprehensively managing information is connected.

  As shown in FIGS. 2A to 4, the cassette storage bag 13 </ b> A is a cover for storing the radiation detection cassette 15 </ b> A, shields outside light, transmits the radiation 14, has moisture resistance, and has the radiation. 14 is made of a material that shields electromagnetic waves different from 14 (for example, radiation from a radiation source different from the radiation source 16) and has flexibility. An example of the cassette storage bag 13A that satisfies such conditions is an aluminum light shielding bag. The cassette storage bag 13A is securely sterilized to prevent contamination of the radiation detection cassette 15A with body fluids and blood in facilities such as hospitals, and to prevent nosocomial infections such as infection of the patient 18. Usually, it is disposable after each treatment. 2A is a perspective view of the radiation detection apparatus 10A when viewing the front surface 28a, and FIG. 2B is a perspective view of the radiation detection apparatus 10A when viewing the back surface 28b.

  Further, in the cassette storage bag 13A, the opening 28c for inserting the radiation detection cassette 15A is formed by, for example, a lid portion 28d formed by extending the front surface 28a (the surface facing the irradiation surface 33 of the radiation detection cassette 15A). Can be occluded. The lid portion 28d can be brought into close contact with the back surface 28b (the surface opposite to the front surface 28a) by the sealing tape 31, whereby the radiation detection cassette 15A can be sealed in the cassette storage bag 13A.

  On the front surface 28a of the cassette storage bag 13A, there is shown a frame (mark) 29a corresponding to the imaging area, the mark 29c indicating the center of the imaging area, and the radiation detection cassette 15A. If the mark 29b or the like indicating the insertion direction is printed with a material that transmits the radiation 14, it is possible to prevent the doctor or the radiographer from mistakenly inserting the radiation detection cassette 15A in the cassette storage bag 13A. .

  On the other hand, the radiation detection cassette 15A stored in the cassette storage bag 13A is a flexible sheet-like cassette as shown in FIGS. 2A to 5, and the case 36 made of a material that transmits the radiation 14 includes: Before being stored in the cassette storage bag 13A, it is flexible and can be wound into a roll and stored in a storage box (not shown) or the like. On the other hand, when stored in the cassette storage bag 13A, It becomes a shape developed with respect to the patient 18 in a substantially planar shape.

  Inside the case 36 are a grid 34 that removes scattered radiation 14 from the patient 18, a radiation detector 40 that detects the radiation 14 transmitted through the patient 18, and a lead sheet 42 that absorbs backscattered radiation 14. Are arranged in order with respect to the irradiation surface (imaging surface) 33 on the patient 18 side. The grid 34, the radiation detector 40, and the lead sheet 42 are also flexible. Further, the irradiation surface 33 of the case 36 may be configured as a grid 34.

As shown in FIG. 5, the radiation detector 40 includes a scintillator 72 made of a phosphor such as GOS (Gd ₂ O ₂ S) or CsI that temporarily converts the radiation 14 transmitted through the patient 18 into visible light, and a thin film transistor (TFT). : Thin Film Transistor) 52 (see FIG. 6), a TFT layer 74 capable of transmitting radiation 14 and visible light, and a solid-state detection element (hereinafter referred to as a pixel) made of a material such as amorphous silicon (a-Si). And the photoelectric conversion layer 76 that converts the visible light into an electric signal using the layer 50 is integrally laminated on the substrate 71 in order.

  Further, as shown in FIG. 3, the case 36 includes a battery 44 that is a power source of the radiation detection cassette 15A, a cassette control unit 46 that drives and controls the radiation detector 40 by supplying power from the battery 44, and a transceiver. 48 is further accommodated. The cassette controller 46 and the transmitter / receiver 48 are preferably provided with a lead sheet or the like on the irradiation surface 33 side of the case 36 in order to avoid damage caused by the irradiation of the radiation 14. The battery 44 supplies power not only to the cassette control unit 46 but also to the radiation detector 40 and the transceiver 48.

  Further, in the transceiver 48, when the radiation detection cassette 15A is stored in the cassette storage bag 13A, a cylindrical electrical insulating member 30 attached to a hole formed in the lid portion 28d of the cassette storage bag 13A. A rod-shaped antenna (first antenna) 32 that penetrates through and can protrude outside is provided. As described above, since the cassette storage bag 13A shields electromagnetic waves different from the radiation 14, the wireless communication means 49 including the antenna 32 and the transmitter / receiver 48 has the antenna 32 penetrating the electrical insulating member 30 and externally. It is possible to transmit and receive a signal including the information of the radiation 14 detected by the radiation detector 40 by wireless communication between the antenna 32 and the console 20 only when the antenna protrudes into the position. The electrical insulating member 30 is provided to avoid electrical contact between the material (aluminum) constituting the cassette storage bag 13A and the antenna 32.

  The antenna 32 is extendable and retractable along the direction from the transmitter / receiver 48 to the electrical insulating member 30 (left and right direction in FIG. 4). Therefore, when the radiation detection cassette 15A is inserted into the cassette storage bag 13A, for example, the antenna 32 is extended from the transceiver 48 by a certain length (a length that does not obstruct the blocking of the opening 28c by the lid 28d). Then, after passing the tip of the antenna 32 through the electrical insulating member 30, the opening 28c is closed by the lid 28d, and then the antenna 32 is extended to a predetermined length, so that the antenna 32 and the console 20 are A signal can be transmitted and received by wireless communication. Note that a folding antenna may be used in place of the telescopic antenna 32 described above.

  Moreover, the arrangement | positioning location of the electrical insulation member 30 is not limited to the cover part 28d as shown to FIG. 2A-FIG. 4, It does not interfere with irradiation of the radiation 14, and is radio | wireless between the consoles 20. Any place where signals can be transmitted and received by communication is acceptable. For example, the electrical insulating member 30 may be disposed on the side portion of the cassette storage bag 13A, and the antenna 32 may protrude from the side portion.

  Further, even when the hole formed in the lid portion 28d and the vicinity thereof are covered with an electric insulating material instead of the electric insulating member 30, the same effect as the above-described electric insulating member 30 can be obtained.

  FIG. 6 is a circuit configuration block diagram of the radiation detector 40. In the radiation detector 40, a photoelectric conversion layer 76 in which each pixel 50 made of a substance such as a-Si that converts visible light into an electric signal is formed is arranged on an array of TFTs 52 (TFT layer 74). It has the structure. In this case, in each pixel 50, electric charges generated by converting visible light into electric signals are accumulated, and the electric charges can be read out as image signals by sequentially turning on the TFTs 52 for each row.

  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 scan driver 58, and each signal line 56 is connected to a multiplexer 66. 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 that switches the gate lines 54, and an address decoder 60 that outputs 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 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. The amplifier 62, the sample hold circuit 64, the multiplexer 66, and the A / D converter 70 constitute a read circuit unit (read unit) 69.

  Further, the cassette controller 46 of the radiation detection cassette 15A includes an address signal generator 82, an image memory 84, and a cassette ID memory 86, as shown in FIG.

  The address signal generator 82 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 84 stores the radiation image information detected by the radiation detector 40. The cassette ID memory 86 stores cassette ID information for specifying the radiation detection cassette 15A.

  The wireless communication means 49 constituting the transceiver 48 and the antenna 32 transmits the cassette ID information stored in the cassette ID memory 86 and the radiation image information stored in the image memory 84 to the console 20 by wireless communication.

  The radiation detection apparatus 10A and the radiation image capturing system 12A according to the first embodiment are basically configured as described above, and the operation thereof will be described next.

  Patient information of the patient 18 to be imaged is registered in advance in the console 20 prior to imaging. If the imaging region and imaging method are determined in advance, these imaging conditions are also registered in advance.

  When taking radiographic image information in an operating room, a medical examination or a round in a hospital, a doctor or a radiographer takes out a roll-shaped radiation detection cassette 15A from a storage box (not shown) and expands it in a planar shape. Next, the radiation detection cassette 15A is inserted in the direction indicated by the mark 29b in a state where the lid portion 28d and the back surface 28b of the cassette storage bag 13A are spaced apart (opening portion 28c is open). Next, the doctor or radiologist stretches the antenna 32 from the radiation detection cassette 15A to such a length that does not obstruct the blocking of the opening 28c by the lid 28d, and the tip of the antenna 32 is electrically insulated from the electrical insulating member 30. Pass through. Thereafter, the opening 28c is closed by the lid 28d, and the radiation detection cassette 15A is sealed in the cassette storage bag 13A. Then, the doctor or the radiographer sets the antenna 32 to a predetermined length (between the antenna 32 and the console 20). To a length that allows wireless communication on the Internet).

  Next, the doctor or radiologist installs the radiation detection apparatus 10A at a predetermined position between the patient 18 and the bed, for example, with the front surface 28a (irradiation surface 33) on the radiation source 16 side. After appropriately moving the source 16 to a position facing the radiation detection apparatus 10A, imaging is performed by operating the imaging switch of the radiation source 16. Due to the operation of the imaging switch, the radiation source 16 requests the console 20 to transmit imaging conditions by wireless communication, and the console 20 receives the imaging region of the patient 18 based on the received request. The imaging conditions related to are transmitted to the radiation source 16. When receiving the imaging conditions, the radiation source 16 irradiates the patient 18 with radiation 14 having a predetermined dose according to the imaging conditions.

  The radiation 14 transmitted through the patient 18 passes through the front surface 28a of the cassette storage bag 13A, and after the scattered radiation is removed by the grid 34 of the radiation detection cassette 15A, the radiation detector 40 is irradiated. The scintillator 72 constituting the radiation detector 40 emits visible light having an intensity corresponding to the intensity of the radiation 14, and each pixel 50 constituting the photoelectric conversion layer 76 converts the visible light into an electric signal and accumulates it as an electric charge. To do. Next, the charge information which is the radiation image information of the patient 18 held in each pixel 50 is read according to the address signal supplied from the address signal generation unit 82 constituting the cassette control unit 46 to the line scanning drive unit 58 and the multiplexer 66. It is.

  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 82 to select 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 first and second gates. 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 82, sequentially switches the switch SW2, and is connected to the gate line 54 selected by the line scan driving unit 58. Radiation image information that is charge information held in each pixel 50 is sequentially read out via a signal line 56.

  The radiation image information read from each pixel 50 connected to the selected gate line 54 of the radiation detector 40 is amplified by each amplifier 62, sampled by each sample hold circuit 64, and passed through the multiplexer 66. Is supplied to the A / D converter 70 and converted into a digital signal. The radiographic image information converted into the digital signal is temporarily stored in the image memory 84 of the cassette control unit 46.

  Similarly, the address decoder 60 of the line scan driver 58 sequentially switches the switch SW1 according to the address signal supplied from the address signal generator 82, and the charge held in each pixel 50 connected to each gate line 54. Radiation image information as information is read out via the signal line 56 and stored in the image memory 84 of the cassette control unit 46 via the multiplexer 66 and the A / D converter 70.

  The radiation image information stored in the image memory 84 is transmitted to the console 20 by wireless communication via the transceiver 48 and the antenna 32. The console 20 performs predetermined image processing on the received radiation image information, and then stores the radiation image information in association with the registered patient information of the patient 18. The radiographic image information subjected to the image processing is transmitted from the console 20 to the display device 22, and the display device 22 displays the radiographic image information.

  After the imaging of the patient 18 is completed, the doctor or radiologist contracts the antenna 32 protruding outside from the electrical insulating member 30 and stores it in the radiation detection cassette 15A, and then separates the lid portion 28d from the back surface 28b to open the opening. The radiation detection cassette 15A is taken out from the portion 28c, the case 36 is wound up in a roll shape, and the radiation detection cassette 15A is stored in a storage box. On the other hand, the cassette storage bag 13A after the radiation detection cassette 15A is taken out is discarded because imaging (one process) is completed.

  As described above, according to the radiation detection apparatus 10A and the radiographic imaging system 12A according to the first embodiment, the cassette storage bag 13A that stores the radiation detection cassette 15A blocks external light and transmits the radiation 14. Therefore, the radiation detection cassette 15A (radiation detector 40) can be reliably shielded from the external light, and as a result, highly accurate radiation image information can be acquired.

  In this case, the cassette storage bag 13A blocks outside light, transmits radiation 14, has moisture resistance, and shields electromagnetic waves different from the radiation 14 (such as radiation from a radiation source different from the radiation source 16). And made of a flexible material (aluminum shading bag). Accordingly, it is possible to prevent body fluid and blood from being mixed into the radiation detection cassette 15A and to prevent hospital infection such as infection to the patient 18. In addition, it is possible to reliably prevent noise caused by external light or noise caused by electromagnetic waves different from the radiation 14 from being superimposed on the radiation image information, so that more accurate radiation image information can be obtained. Become. Furthermore, since the cassette storage bag 13A has flexibility, handling is easy.

  Further, since the scintillator 72, the TFT layer 74, and the photoelectric conversion layer 76 are integrally laminated in this order on the substrate 71 (the photoelectric conversion layer 76, the TFT layer 74, and the scintillator 72 are arranged in this order with respect to the irradiation surface 33). The visible light generated by the scintillator 72 can be efficiently converted into an electric signal by the photoelectric conversion layer 76, and as a result, high-quality radiation image information can be obtained. In addition, since the external light is blocked by the cassette storage bag 13A and does not reach the scintillator 72 and the photoelectric conversion layer 76, the noise superimposed on the radiation image information due to the external light as compared with Patent Document 1. Can be reliably prevented.

  Further, since the radiation detection cassette 15A has flexibility, the radiation detection cassette 15A can be rolled up and stored in a storage box or the like, while being stored in the cassette storage bag 13A. Since it is sometimes developed in a planar shape, the handleability of the radiation detection apparatus 10A can be remarkably improved.

  Furthermore, in the first embodiment, signals are transmitted and received by radio communication between the console 20, the radiation detection apparatus 10A, the radiation source 16, and the display device 22, so that a cable for transmitting and receiving signals is not necessary. Therefore, there is no risk of disturbing the work of the doctor or radiologist. Therefore, the doctor or radiologist can perform his / her work efficiently. In particular, the antenna 32 is extended from the transceiver 48 of the radiation detection cassette 15A through the electrical insulating member 30 of the cassette storage bag 13A to the outside, and signals are transmitted and received between the antenna 32 and the console 20 by wireless communication. Therefore, even if the radiation detection cassette 15A is stored in the cassette storage bag 13A, transmission / reception of signals between the radiation detection cassette 15A and the console 20 can be performed reliably.

  Furthermore, in the first embodiment, the radiographic image information is captured due to the operation of the imaging switch of the radiation source 16 by the doctor or radiologist, but the radiation due to the operation of the console 20 by the doctor or radiologist. Image information may be taken.

  Furthermore, in 1st Embodiment, you may replace 10 A of radiation detection apparatuses with the structure of FIG. In FIG. 7, the TFT layer 74, the photoelectric conversion layer 76, and the scintillator 72 are integrally laminated in this order from the substrate 71 toward the irradiation surface 33 side. Even in this case, since the visible light converted by the scintillator 72 can be converted into an electric signal by the photoelectric conversion layer 76, it is a matter of course that the above-described effects can be obtained.

  Furthermore, in the first embodiment, instead of the above-described configuration, for example, the dose of the incident radiation 14 is directly converted into an electric signal by a photoelectric conversion layer using a solid detection element made of a substance such as amorphous selenium (a-Se). May be converted to

  Also, radiation image information can be obtained by 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 from a flexible organic EL (Electro-Luminescence) panel or the like, 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 (refer to Japanese Patent Laid-Open No. 2000-105297). .

  Furthermore, in the first embodiment, a stimulable phosphor panel capable of accumulating radiation energy as radiation image information in the phosphor and extracting the radiation image information as stimulated emission light by irradiating excitation light, You may comprise as a radiation conversion panel which has flexibility.

  Furthermore, in the first embodiment, instead of the radiation detection cassette 15A in which the radiation detector 40 is accommodated in the sheet-like case 36, the cassette may be configured by accommodating the radiation detector 40 in a rectangular housing. Of course, the above-described effects can be easily obtained by storing the cassette in the cassette storage bag 13A.

  Further, instead of the cassette storage bag 13A, the radiation detection cassette 15A is provided in a rectangular casing that shields external light, transmits radiation 14, has moisture resistance, and shields electromagnetic waves different from the radiation 14. May be stored. In this case, since the casing does not have flexibility, the effect of having flexibility cannot be obtained. However, the external light is shielded, the radiation 14 is transmitted, and the moisture 14 has moisture resistance. The effect obtained by shielding electromagnetic waves different from the above can be easily obtained.

  Further, in the first embodiment, as illustrated in FIGS. 5 and 7, the case where the radiation detector 40 is configured by integrally forming the scintillator 72, the TFT layer 74, and the photoelectric conversion layer 76 has been described. Instead of this configuration, the grid 34, the scintillator 72, the TFT layer 74 and the photoelectric conversion layer 76, the lead sheet 42, the battery 44, the cassette control unit 46, and the transceiver 48 unit are formed separately. When these are stored in the cassette storage bag 13A, the radiation detection cassette 15A is configured by the grid 34, the scintillator 72, the TFT layer 74 and the photoelectric conversion layer 76, the lead sheet 42, and the unit. May be. In this case, for example, a plurality of pocket-shaped receiving portions are provided in the cassette storage bag 13A. In these receiving portions, the grid 34, the scintillator 72, the TFT layer 74, the photoelectric conversion layer 76, the lead sheet 42, After housing the units, the unit, the scintillator 72, the TFT layer 74, and the photoelectric conversion layer 76 are connected by a cable or the like to configure the radiation detection cassette 15A.

  Even in this case, when the cassette storage bag 13A cannot be used, the radiation detection cassette 15A stored in the cassette storage bag 13A can be reused as the radiation detection cassette 15A of the new cassette storage bag 13A. is there. Further, since each component is a separate body, it can be easily replaced with a scintillator 72 (high-definition type or high-sensitivity type scintillator) having different specifications depending on the photographing conditions, so that it is easy to use. That is, since the scintillator 72 is a relatively expensive part, it can be reused, or the scintillator 72 can be replaced according to imaging conditions, thereby reducing the cost of the radiation detection apparatus 10A. Can be realized.

  Next, a radiation detection apparatus 10B and a radiation image capturing system 12B according to the second embodiment will be described with reference to FIGS.

  In addition, in the radiation detection apparatus 10B and the radiographic imaging system 12B, the same reference numerals are given to the same components as those in the radiological detection apparatus 10A and the radiographic imaging system 12A (see FIGS. 1 to 7) according to the first embodiment. Detailed description thereof will be omitted.

  In the radiation detection apparatus 10B and the radiation image capturing system 12B according to the second embodiment, the printed antenna (second antenna) 102 is printed on the electrical insulating layer 100 formed on the back surface 28b of the cassette storage bag 13B, and the transceiver 48 is used. Between the wireless communication means 49 and the console 20 by connecting the cable 96 to the printed antenna 102 using the connector 90 on the cable 96 side and the connector 92 on the cable 98 side. This is different from the radiation detection apparatus 10A and the radiation image capturing system 12A according to the first embodiment in that signals can be transmitted and received by wireless communication.

  In this case, the doctor or radiologist inserts the radiation detection cassette 15B in the direction indicated by the mark 29b in a state where the lid portion 28d and the back surface 28b of the cassette storage bag 13B are separated from each other, and then the cable from the transceiver 48 The 96 connectors 90 are connected to the connector 92 of the cable 98 from the printed antenna 102. Next, the opening 28c is closed by the lid 28d, and the radiation detection cassette 15B is sealed in the cassette storage bag 13B. As a result, signals can be transmitted and received between the wireless communication means 49 and the console 20, and the patient 18 can be imaged using the radiation detection apparatus 10B.

  Here, the electrical insulating layer 100 is formed on the back surface 28b of the cassette storage bag 13B in order to ensure electrical insulation between the printed antenna 102 and the material (aluminum) constituting the cassette storage bag 13B. In addition, the arrangement | positioning location of the printed antenna 102 and the electric insulation layer 100 is not limited to the back surface 28b side shown to FIG. 9B, FIG. 10, and FIG. In other words, it may be a location that does not hinder the irradiation of the radiation 14 and can transmit and receive signals by radio communication with the console 20, for example, the lid portion 28d or the cassette storage bag 13B. You may form in the side part.

  According to the radiation detection apparatus 10B and the radiation image capturing system 12B according to the second embodiment, the connector 90 of the cable 96 from the transmitter / receiver 48 and the connector 92 of the cable 98 from the printed antenna 102 are connected to each other, thereby wirelessly. Since transmission / reception of signals between the communication means 49 and the console 20 is possible, in addition to the effects of the radiation detection apparatus 10A and the radiographic imaging system 12A according to the first embodiment described above, the electrical insulating member 30 is unnecessary. Thus, the light shielding property, moisture proofing property, and shielding property against electromagnetic waves different from the radiation 14 of the cassette storage bag 13B can be ensured more reliably.

  The first and second embodiments described above can employ the following configurations.

  That is, when the radiation detection apparatuses 10A and 10B are used in an operating room or the like, there is a possibility that blood or other germs may adhere. Therefore, the cassette storage bags 13A and 13B are made waterproof and hermetically sealed, and sterilized and washed as necessary, so that one radiation detection device 10A and 10B can be used repeatedly.

  Further, the wireless communication between the radiation detection apparatuses 10A and 10B 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, a display unit 506 that displays various types of information related to the radiation detection cassette 500 is disposed outside the imaging region of the radiation detection cassette 500. The display unit 506 displays the ID information of the patient 18 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, and the like. In this case, for example, the radiologist confirms the patient 18 in accordance with the ID information displayed on the display unit 506 and confirms in advance that the radiation detection cassette 500 is in a usable state, so that an optimal radiation image is obtained. Information can be taken.

  Further, by forming a hole 508 in the case 502 and tying the hole 508 with a string (not shown), the radiation detection cassette 500 can be easily handled and carried.

  Furthermore, it is preferable to arrange an input terminal 510 of the AC adapter, a USB (Universal Serial Bus) terminal 512, and a card slot 516 for loading the memory card 514.

  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 20. That is, 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. 13, a cradle 518 for charging the battery 44 built in the radiation detection cassettes 15A and 15B is preferably disposed at a necessary location in the operating room or hospital. In this case, the cradle 518 not only charges the battery 44 but also transmits / receives necessary information to / from external devices such as the RIS 24, the HIS 26, and the console 20 using the wireless communication function or the wired communication function of the cradle 518. You may make it perform. The information to be transmitted / received can include radiation image information recorded in the radiation detection cassettes 15A and 15B charged in the cradle 518.

  In addition, a display unit 520 is provided in the cradle 518, and necessary information including the state of charge of the radiation detection cassettes 15A and 15B and the radiation image information acquired from the radiation detection cassettes 15A and 15B is displayed on the display unit 520. May be displayed.

  Also, a plurality of cradle 518 is connected to a network, and the charging states of radiation detection cassettes 15A and 15B charged in each cradle 518 are collected via the network, and radiation detection cassettes 15A and 15B in a usable charging state are collected. It is also possible to configure so that the location of the can be confirmed.

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

1 is a configuration block diagram of a radiographic image capturing system according to a first embodiment. 2A and 2B are perspective views of the radiation detection apparatus of FIG. It is a perspective view of the radiation detection apparatus of FIG. FIG. 4 is a cross-sectional view taken along line IV-IV in FIG. 3. It is sectional drawing along the VV line of FIG. It is a circuit block diagram of the radiation detector of FIG. It is sectional drawing along the VII-VII line of FIG. It is a block diagram of the configuration of the radiographic image capturing system of the second embodiment. 9A and 9B are perspective views of the radiation detection apparatus of FIG. It is a perspective view of the radiation detection apparatus of FIG. It is sectional drawing along the XI-XI line of FIG. 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

10A, 10B ... Radiation detection devices 12A, 12B ... Radiation imaging system 13A, 13B ... Cassette storage bag 14 ... Radiation 15A, 15B ... Radiation detection cassette 16 ... Radiation source 18 ... Patient 28a ... Front 28b ... Back 28c ... Opening 28d ... lid 30 ... electrical insulating member 32 ... antenna 33 ... irradiation surface 36 ... case 40 ... radiation detector 44 ... battery 46 ... cassette control part 48 ... transceiver 49 ... wireless communication means 69 ... readout circuit part 72 ... scintillator 74 ... TFT layer 76 ... photoelectric conversion layer 90, 92 ... connector 96, 98 ... cable 100 ... electrical insulation layer 102 ... printed antenna

Claims (16)

A scintillator that converts the radiation that has passed through the subject into visible light, and a radiation conversion panel that includes a solid-state detection element that converts the visible light into an electrical signal;
A housing for housing the radiation conversion panel and shielding external light, and transmitting the radiation;
A radiation detection apparatus comprising: The apparatus of claim 1.
The radiation conversion panel further includes a reading unit that reads the electrical signal from the solid-state detection element and acquires the read electrical signal as radiation image information. The apparatus according to claim 1 or 2,
In the radiation conversion panel, the solid-state detection element and the scintillator are arranged in this order with respect to the subject, or the scintillator and the solid-state detection element are arranged in this order. . The device according to any one of claims 1 to 3,
The radiation conversion panel is configured by integrally forming the scintillator and the solid state detection element, or the scintillator and the solid state detection element are separately formed, and the scintillator and the solid state detection element are A radiation detection apparatus configured to be stored in the storage body. The apparatus of claim 4.
When the scintillator and the solid state detection element are formed separately, the storage body is configured to store the scintillator and the solid state detection element at predetermined locations in the storage body, respectively. A radiation detection device. In the apparatus of any one of Claims 1-5,
The radiation detection device is characterized in that the radiation conversion panel has flexibility. The apparatus of claim 6.
The radiation conversion panel is housed in a flexible radiation detection cassette,
The radiation detection apparatus according to claim 1, wherein the radiation detection cassette is made of a material that transmits the radiation and is stored in the storage body. In the apparatus of any one of Claims 1-7,
Radiation further comprising: wireless communication means capable of wireless communication with the outside; a control unit that controls the radiation conversion panel; and a battery that drives the radiation conversion panel, the control unit, and the wireless communication means. Detection device. The apparatus of claim 8.
The wireless communication means includes a transceiver housed in the housing body, and a first antenna that can protrude from the transceiver body through a hole formed in the housing body. Radiation detection device. The apparatus of claim 8.
The radio communication device according to claim 1, wherein the wireless communication unit includes a transceiver housed in the housing body and a second antenna provided in the housing body. The apparatus of claim 10.
The radiation detection apparatus according to claim 2, wherein the second antenna is a printed antenna printed on an electrical insulating layer formed on a surface of the housing. The apparatus of claim 11.
The radio communication unit further includes a cable from the transceiver, a cable connected to the second antenna, and a connector for connecting the cables. The apparatus according to any one of claims 1 to 12,
The radiation detector is characterized in that the container is made of a material that has moisture resistance and shields electromagnetic waves different from the radiation. The device according to any one of claims 1 to 13,
The radiation detector according to claim 1, wherein the storage body is a flexible storage bag.   A radiation image, comprising: the radiation detection apparatus according to claim 1; a radiation source that outputs the radiation; and a control device that controls the radiation source and the radiation detection apparatus. Shooting system. The system of claim 15, wherein
The radiation detection apparatus transmits the radiation image information converted by the radiation conversion panel to the control device by wireless communication.

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