JP7293777B2 - medical imaging system - Google Patents

Description

The present invention relates to medical imaging systems.

2. Description of the Related Art Conventionally, it is known that an operator such as a doctor or an engineer performs radiographic imaging of a patient at a hospital ward or the like, using an FPD (Flat Panel Detector) as a radiographic imaging apparatus. An operator brings a medical care vehicle having a radiation generator and an FPD to the site of the rounds, irradiates the patient with radiation emitted from the radiation generator, and images the radiation transmitted through the patient by the FPD to obtain a radiographic image. Radiography is performed by generating data.

There may be a plurality of patients to be imaged at the rounds, and it is necessary to group the plurality of imaged radiographic image data for each patient. For this reason, the operator notes each patient and the characteristic information of the imaging on paper at the time of imaging. , the patient and the radiographic image data are associated with each other.

However, since the operator has to take notes on paper and check the image counter of the FPD one by one, the work of the operator is complicated. For this reason, during radiography of a patient, a dummy image is generated as segmentation information of the patient in response to an operator operating an operation button provided on the radiographic imaging apparatus or a change in posture of the radiographic imaging apparatus. A radiation imaging system is known (see Patent Document 1).

JP 2016-135231 A

However, in the radiographic imaging system described in Patent Document 1, it is necessary to prepare an operation button and a dedicated sensor for the radiographic imaging device. may not be guaranteed. In that case, the delimiter information becomes information different from the actual examination, and there is a risk of patient mix-up. Therefore, when the radiographic image data and delimiter information are loaded from the radiographic imaging apparatus to the imaging control apparatus, the operator needs to check carefully before loading, which is a complicated task. Therefore, there is a demand to easily generate supplementary information such as delimiter information to be supplemented to radiation image data.

SUMMARY OF THE INVENTION An object of the present invention is to easily generate incidental information of radiation image data.

In order to solve the above problems, the medical imaging system of the invention according to claim 1 comprises:
imaging means for generating radiation image data from incident radiation;
a radiographic imaging apparatus comprising: a first storage unit that stores the generated radiographic image data;
a mobile terminal wirelessly connected to the radiographic imaging device and carried by an operator;
The mobile terminal is
an operation means for receiving an operation input of incidental information corresponding to the generated radiation image data;
and a first control means for transmitting the operationally input additional information to the radiographic imaging apparatus,
The radiographic imaging device,
a second control means for receiving the incidental information and storing the incidental information in the first storage means in association with the stored radiation image data ;
The incidental information includes image rotation information indicating the direction and amount of rotation to be applied to the generated radiographic image data, or image inversion information indicating the direction of inversion to be applied to the generated radiographic image data.

The medical imaging system of the invention according to claim 2,
imaging means for generating radiation image data from incident radiation;
a radiographic imaging apparatus comprising: a first storage unit that stores the generated radiographic image data;
A mobile terminal that is communicatively connected to the radiographic imaging device,
The mobile terminal is
an operation means for receiving an operation input of incidental information corresponding to the generated radiation image data;
a first control unit that transmits the incidental information that has been operated and input to the radiographic imaging apparatus;
display means;
The radiographic imaging device,
a second control means for receiving the incidental information and storing the incidental information in the first storage means in association with the stored radiation image data;
The first control means receives the generated radiographic image data from the radiographic imaging device and causes the display means to display the data;
the operation means receives an operation input of supplementary information corresponding to the displayed radiation image data ;
The incidental information includes image rotation information indicating the direction and amount of rotation to be applied to the generated radiographic image data, or image inversion information indicating the direction of inversion to be applied to the generated radiographic image data.
The medical imaging system of the invention according to claim 3 is the medical imaging system according to claim 1 or 2,
The incidental information includes delimiter identification information for grouping a plurality of radiographic image data.

The invention according to claim 4 is the medical imaging system according to claim 2 ,
When radiographic image data is generated by the imaging means, the second control means adds image identification information to the generated radiographic image data and associates the radiographic image data with the image identification information. storing in the first storage means, transmitting the radiation image data and the image identification information to the portable terminal;
The first control means receives the radiographic image data and the image identification information from the radiographic imaging device and causes the display means to display the radiographic image data ;
The first control means transmits the incidental information input by operation and image identification information corresponding to the incidental information to the radiographic imaging apparatus,
The second control means receives the transmitted incidental information and image identification information, uses the image identification information to associate the incidental information with the stored radiation image data, and stores the incidental information in the first storage. Store in means.

The invention according to claim 5 is the medical imaging system according to claim 2 or 4,
The first control means subjects the received radiographic image data to at least one of correction processing dependent on the radiographic imaging device, gradation processing, and thinning processing, and outputs the data to the display means. display.

The invention according to claim 6 is the medical imaging system according to claim 2, 4 or 5 ,
The first control means receives information about the radiographic imaging apparatus from the radiographic imaging apparatus and causes the display means to display the information.

The invention according to claim 7 is the medical imaging system according to any one of claims 1 to 6 ,
The supplementary information includes re-imaging identification information indicating that the generated radiographic image data is a re-imaging, patient information related to a patient corresponding to the generated radiographic image data, and the generated radiographic image data. At least one of corresponding text information and operator information about an operator corresponding to the generated radiation image data is included.

The invention according to claim 8 is the medical imaging system according to any one of claims 1 to 5,
An imaging control device that is communicatively connected to the radiographic imaging device,
The imaging control device is
a second storage means;
a third control means for receiving the radiographic image data and accompanying information stored in the first storage means from the radiographic imaging apparatus and storing the radiographic image data in the second storage means after capturing the radiographic image data; , have

The invention according to claim 9 is the medical imaging system according to claim 8 ,
The third control means, after storing the radiographic image data and the incidental information in the second storage means, transmits storage completion information of the storage to the radiographic imaging apparatus,
After receiving the storage completion information, the second control means deletes the stored radiation image data and accompanying information from the first storage means.

According to the present invention, supplementary information of radiation image data can be easily generated.

1 is a block diagram showing a medical imaging system according to an embodiment of the present invention; FIG. 1 is a diagram showing a configuration of part of a medical imaging system at a visit destination; FIG. It is a block diagram which shows the functional structure of FPD. 2 is a block diagram showing the functional configuration of a mobile terminal; FIG. 2 is a block diagram showing the functional configuration of an imaging control device; FIG. 4 is a sequence diagram showing operations of the FPD, mobile terminal, and imaging control device; FIG. It is a figure which shows several radiographic image data divided into two groups.

Embodiments according to the present invention will be described with reference to the accompanying drawings. It should be noted that the present invention is not limited to the illustrated examples.

First, referring to FIGS. 1 and 2, the overall device configuration of this embodiment will be described. FIG. 1 is a block diagram showing a medical imaging system 1 of this embodiment. FIG. 2 is a diagram showing a configuration of part of the medical imaging system 1 at the rounds destination 2. As shown in FIG.

A medical imaging system 1 is provided in a medical facility such as a hospital. This is an imaging system for radiographic rounds. As shown in FIG. 1 , the medical imaging system 1 includes an FPD 10 as a radiographic imaging device, a mobile terminal 20 , a medical examination vehicle 30 , an imaging control device 40 and a cradle 50 .

As shown in FIG. 2, an operator 6 such as a doctor or an engineer brings an FPD 10, a portable terminal 20, and a mobile inspection vehicle 30 to a mobile inspection site 2 during the round imaging. The mobile inspection vehicle 30 has wheels and is freely movable within, for example, a medical facility, and is equipped with a radiation generator 310 , a radiation generator controller 320 , and a pocket 330 . The radiation generator 310 has a radiation source 311 and an exposure switch 312 .

Radiation source 311 is a portable radiation source that emits radiation. The exposure switch 312 is a switch that receives a press input for instructing the radiation source 311 to start irradiating radiation.

The radiation generation control device 320 has a control unit, a display unit, an operation unit that receives operation input from the operator 6 , and a communication unit that communicates with the radiation generation device 310 . The radiation generation control device 320 controls the radiation generation device 310 via the communication unit according to operation information such as radiation generation condition information input by the operator 6 via the operation unit, Radiography is performed by generating radiation. The radiation generation control device 320 displays operation information and the like on the display unit, but does not have the function of displaying radiation image data generated by the FPD 10 on the display unit. Therefore, the medical imaging system 1 can achieve cost reduction compared to a configuration in which a mobile imaging control device (console) having a radiographic image data display function is mounted on the mobile imaging system 30, and the radiographic image of the mobile imaging control device can be reduced. It is possible to prevent the part related to the data display function from failing to continue the round imaging.

Pocket 330 accommodates FPD 10 . The operator 6 may bring the FPD 10, but the FPD 10 is relatively heavy and may break or malfunction if dropped. there is

An operator 6 carries a mobile terminal 20 . In order to prevent the mobile terminal 20 from interfering with radiography, it is preferable to hang it from the neck of the operator 6 with a strap 20a, for example.

The FPD 10 is a cassette-type portable radiation detection device, and has a radiation image data generation and storage function, a wireless LAN (Local Area Network) communication function with the portable terminal 20, and a Web server function. Also, the FPD 10 is of a type that automatically generates radiation image data upon detection of radiation, but is not limited to this. Further, although one FPD 10 is representatively described in FIGS. 1 and 2, a plurality of FPDs may be provided.

The mobile terminal 20 is composed of, for example, a tablet PC (Personal Computer), and has a function of receiving operation input of information related to radiation imaging by the operator and incidental information of radiation image data, and a function of wireless LAN communication with the FPD 10 and the medical vehicle 30. , has The mobile terminal 20 is not limited to a tablet PC, and may be other mobile terminal devices such as a smart phone and a notebook PC. Also, the mobile terminal 20 is a dedicated machine for round imaging, but is not limited to this, and may be configured to use a general-purpose machine.

The operator 6 inserts the FPD 10, for example, between the subject 5 of the patient lying on the bed 4 and the bed 4, or into an insertion opening provided on the opposite side of the subject 5 of the bed 4 (not shown). By turning on the exposure switch 312 in this state, radiation is emitted from the radiation source 311 of the radiation generator 310 to the subject's 5 to be imaged, for example, the leg, and the subject 5 is radiographed.

The FPD 10 generates and stores radiation image data according to the radiation emitted from the radiation generator 310 to the subject 5 . In this way, radiography is performed on the subjects of a plurality of patients at the rounds destination 2 , and the radiographic image data of the plurality of patients is temporarily stored in the FPD 10 . At this time, the operator 6 generates incidental information such as segmentation identification information of groups for each patient from a plurality of radiation image data by operating the mobile terminal 20, and stores the radiation image data in association with the radiation image data of the FPD 10. .

As shown in FIG. 1, the imaging control device 40 and the cradle 50 are installed in the imaging room 3 for radiography. The imaging control device 40 is a console for normal radiographic imaging using the imaging device in the imaging room 3, and is composed of, for example, a workstation. Further, the imaging control device 40 stores radiographic image data generated by normal radiographic imaging in the radiographic imaging room 3 or radiographic imaging at the visiting destination 2 . The cradle 50 is connected to the imaging control device 40, and when the FPD 10 is placed and electrically connected, the cradle 50 supplies power to the FPD 10 and relays communication between the FPD 10 and the imaging control device 40. .

After radiation imaging at the rounds 2, the operator 6 brings the FPD 10 into the imaging room 3, places it on the cradle 50, and connects it. The imaging control device 40 receives and takes in radiation image data, additional information, and the like stored in the FPD 10 from the FPD 10 via the cradle 50 .

Next, the internal functional configurations of the FPD 10, mobile terminal 20 and imaging control device 40 will be described with reference to FIGS. 3 to 5. FIG. FIG. 3 is a block diagram showing the functional configuration of the FPD 10. As shown in FIG. FIG. 4 is a block diagram showing the functional configuration of the mobile terminal 20. As shown in FIG. FIG. 5 is a block diagram showing the functional configuration of the imaging control device 40. As shown in FIG.

As shown in FIG. 3, the FPD 10 includes a control unit 11 as second control means, an operation unit 12, a storage unit 13 as first storage means, a radiation imaging unit 14 as imaging means, and a wireless It has a communication unit 15 and a wired communication unit 16 . Each part of the FPD 10 is connected via a bus 17 .

The control unit 11 includes a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like. The CPU of the control unit 11 reads the system program and various processing programs stored in the storage unit 13, expands them in the RAM, and controls each unit of the FPD 10 according to the expanded programs.

The operation unit 12 is configured by a switch or the like, receives operation input such as selection of memory mode or normal mode from the operator, and outputs the operation information to the control unit 11 . The memory mode is a mode in which the radiographic image data generated for each imaging at a visit destination or the like is stored in the storage unit 13 as a memory inside the FPD 10 . The normal mode is a mode in which when one radiographic image data is generated by radiography, the radiographic image data is repeatedly transmitted to the console (imaging control device 40).

The storage unit 13 is composed of a non-volatile semiconductor memory such as a flash memory, and stores various programs and data to be executed by the control unit 11 . In particular, the storage unit 13 stores the radiation image data generated by the radiation imaging unit 14 and accompanying information.

The radiation imaging unit 14 is composed of an imaging device such as a CMOS (Complementary Metal Oxide Semiconductor) image sensor that directly converts radiation into an electrical signal as a direct conversion method, or an indirect conversion method such as gadolinium sulfate or cesium iodide. It is composed of a phosphor and an imaging device such as a photodiode that captures light generated by exciting the phosphor with incident radiation as an electric charge. Under the control of the control unit 11 , the radiographic imaging unit 14 generates radiographic image data using an imaging device in accordance with the radiation incident through the subject, and outputs and stores the radiographic image data in the storage unit 13 .

The wireless communication unit 15 has an antenna, a modulation/demodulation unit, a signal processing unit, and the like, and performs wireless communication with an external device such as the mobile terminal 20 using a wireless LAN communication method. Also, the wireless communication unit 15 functions as an access point for wireless LAN communication. The control unit 11 wirelessly communicates with external devices such as the mobile terminal 20 and the console of the medical vehicle 30 via the wireless communication unit 15 . However, the present invention is not limited to this configuration, and an access point may be provided inside or outside the medical examination destination 2, the medical examination vehicle 30, or the like, and the FPD 10 and the mobile terminal 20 may wirelessly communicate via the access point. good.

The wired communication unit 16 is a wired communication unit including terminals connected to the cradle 50 . The control unit 11 performs wired communication with the imaging control device 40 via the wired communication unit 16 and the cradle 50 .

The FPD 10 also has a battery (not shown) such as a secondary battery that supplies power to each part of the FPD 10 .

As shown in FIG. 4, the portable terminal 20 includes a control unit 21 as first control means, an operation unit 22 as operation means, a storage unit 23, a display unit 24 as display means, and a wireless communication unit. 25; Each unit of the mobile terminal 20 is connected via a bus 26 .

The control unit 21 is composed of a CPU, a RAM, and the like. The CPU of the control unit 21 reads the system program and various processing programs stored in the storage unit 23, expands them in the RAM, and controls each unit of the mobile terminal 20 according to the expanded programs.

The operation unit 22 is composed of a touch panel integrally provided on the display screen of the display unit 24 , receives touch input from the operator, and outputs the operation information to the control unit 21 .

The storage unit 23 is composed of a non-volatile semiconductor memory such as a flash memory. The storage unit 23 stores various programs and various data executed by the control unit 21 .

The display unit 24 is configured by an LCD (Liquid Crystal Display), an EL (Electro-Luminescence) display, or the like, and displays various information according to display instructions from the control unit 21 .

The wireless communication unit 25 has an antenna, a modulation/demodulation unit, a signal processing unit, etc., and performs wireless communication with an external device using a wireless LAN communication method or a mobile communication method. In particular, the control unit 21 performs wireless communication with an external device such as the FPD 10 via the wireless communication unit 25 using a wireless LAN communication method.

As shown in FIG. 5, the imaging control device 40 includes a control section 41 as third control means, an operation section 42, a storage section 43 as second storage means, a display section 44, and a wired communication section. 45 and a communication unit 46 . Each unit of the imaging control device 40 is connected via a bus 47 .

The control unit 41 is composed of a CPU, a RAM, and the like. The CPU of the control unit 41 reads the system program and various processing programs stored in the storage unit 43, expands them in the RAM, and controls each unit of the imaging control device 40 according to the expanded programs.

The operation unit 42 includes a keyboard having cursor keys, numeric input keys, various function keys, etc., and a pointing device such as a mouse, and controls instruction information input by key operations on the keyboard and mouse operations. Output to unit 41 . The operation unit 42 may also include a touch panel integrated with the display screen of the display unit 44 . In this case, operation information touch-inputted via the touch panel is output to the control unit 41 .

The storage unit 43 is configured by a storage unit such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive) from which information can be read and written. The storage unit 43 stores various programs and various data executed by the control unit 41 . In particular, the storage unit 43 stores radiographic image data and incidental information loaded from the FPD 10 via the cradle 50 .

The display unit 44 is configured by an LCD, an EL display, or the like, and displays various information according to display instructions from the control unit 41 .

The wired communication unit 45 is connected to the cradle 50 by wire and communicates between the FPD 10 connected to the cradle 50 and the control unit 41 . The communication unit 46 is a communication unit that communicates with an imaging device in the imaging room, an image management server of PACS (Picture Archiving and Communication Systems), and the like via a communication network.

Next, the operation of the medical imaging system 1 will be described with reference to FIGS. 6 and 7. FIG. FIG. 6 is a sequence diagram showing operations of the FPD 10, mobile terminal 20, and imaging control device 40. As shown in FIG. FIG. 7 is a diagram showing radiation image data 61 to 65 divided into groups GA and GB.

In advance, the operator brings at least one FPD 10, the portable terminal 20, and the medical care vehicle 30 to the medical care destination. Then, the operator sets the FPD 10 to the memory mode by inputting an operation to the operation section 12 of the FPD 10 .

As shown in FIG. 6, first, the control unit 11 of the FPD 10 is activated as a web server. In addition, the control unit 21 of the mobile terminal 20 activates a browser program in response to a connection instruction from the operator via the operation unit 22, and the FPD 10 as a Web server via the wireless communication unit 25 from the activated browser. A communication connection is established to establish communication (step S1). At least one FPD 10 is connected for communication with the mobile terminal 20 by step S1.

Then, the control unit 11 of the FPD 10 connected for communication transmits device information of its own device to the portable terminal 20 via the wireless communication unit 15 (step S2). The device information is information such as a unique ID of the FPD 10, a name, and attributes (such as size).

Then, the control unit 11 of the FPD 10 transmits the state information of its own device to the portable terminal 20 via the wireless communication unit 15 (step S3). The state information of the FPD 10 of the device includes the battery charging state, the wireless communication connection state, the number of radiation image data stored in the storage unit 13/maximum number of stored images, the state indicating whether or not imaging is possible, and the state stored in the storage unit 13. This is information such as a thumbnail image list for each image ID of all captured radiographic image data. The control unit 21 of the mobile terminal 20 receives the device information and the state information from the FPD 10 via the wireless communication unit 25 and displays them on the display unit 24 . The control unit 21 of the mobile terminal 20 receives the state information from the FPD 10 via the wireless communication unit 25, and displays it on the display unit 24 together with the device information acquired in step S2.

The operator inputs information for round imaging into the operation unit of the radiation generation control device 320, and the operator adjusts the positions of the radiation source 311 and the FPD 10 for radiographic imaging. The radiation generation control device 320 controls the radiation generation device 310 according to operation information and the like. Then, the radiation generation control device 320 causes the radiation generation device 310 to irradiate the subject with radiation from the radiation source 311 when the operator presses the exposure switch 312 as a trigger.

When the control unit 11 of the FPD 10 detects the radiation emitted from the radiation generator 310 to the subject and transmitted through the subject by the radiation imaging unit 14, the control unit 11 of the FPD 10 generates radiation image data corresponding to the transmitted radiation (step S4).

Then, the control unit 11 of the FPD 10 assigns an image ID to the radiation image data generated in step S4, associates the generated radiation image data with the image ID, and stores the radiation image data in the storage unit 13 ( step S5). The image ID is identification information of radiation image data, and is, for example, an ascending count value such as 1, 2, 3, and so on. In addition, in step S<b>5 , the FPD 10-dependent offset, gain, and other correction processing may be performed and then stored in the storage unit 13 .

Then, the control unit 11 of the FPD 10 transmits the image ID and radiation image data saved in step S5 to the portable terminal 20 via the wireless communication unit 15 (step S6). The control unit 21 of the mobile terminal 20 receives the image ID and radiation image data from the FPD 10 via the wireless communication unit 25 .

Then, the control unit 21 of the mobile terminal 20 performs image processing for previewing the radiographic image data received in step S6, and displays it on the browser screen of the display unit 24 together with the image ID received in step S6 (step S7). . The image processing in step S7 is, for example, at least one of correction processing for defects dependent on the FPD 10, gradation processing, and thinning processing (reduction processing). Note that the control unit 21 enlarges, reduces, rotates, or inverts the radiographic image data being displayed according to input of instruction information for enlargement, reduction, rotation, or inversion from the operator via the operation unit 22, and displays the data on the display unit. 24 browser screens can be displayed. Further, in step S7, the device information of the FPD 10 received in step S2 and the state information of the FPD 10 received in step S3 may also be displayed on the browser screen of the display unit 24. FIG.

Then, the control unit 21 of the mobile terminal 20 receives input of supplementary information corresponding to the radiation image data displayed in step S7 via the operation unit 22 (step S8). Supplementary information is
- Separation identification information for separating the same patient as one group for a plurality of radiographic image data,
- failed identification information indicating that the radiation image data is a failed image;
- Re-imaging identification information indicating that the radiation image data is a re-imaging image re-imaging after a failure;
・Patient information,
・Text information,
・Image rotation information, image reversal information,
・ Operator information,
at least one of

The incidental information will be described with reference to FIG. As shown in FIG. 7, radiation image data 61 to 65 are taken in order. The accompanying information 71-75 input in step S8 are associated with the radiographic image data 61-65. For example, the incidental information 71-75 are included in the radiation image data 61-65, respectively, but may be separate data.

Radiation image data 61 to 63 are for patient A as the subject, and radiation image data 64 and 65 are for patient B as the subject. Therefore, in step S8 after the radiographic image data 61 and 62 are captured, the segment identification information is not input, and in step S8 after the radiographic image data 63 is captured, the segment identification information is input and included in the incidental information. Therefore, the radiation image data 61 to 63 are divided into patient A groups GA. Similarly, radiographic image data 64 and 65 are divided into patient B groups GB.

The imaging failure identification information is information indicating failure in radiographic image data imaging, and may include the reason for imaging failure. The reason for the failure is, for example, that the positioning of the subject with respect to the FPD 10 is poor, the dose of radiation during imaging is insufficient or excessive, and a foreign object such as a necklace of the subject is captured. In FIG. 7, in step S8 after the radiographic image data 64 is captured, the identification information of the imaging failure is input and included in the incidental information 72. FIG.

The image rotation information is information indicating the direction and amount of rotation required for radiation image data. Information indicating that the FPD 10 needs to be rotated 90 degrees to the right later, and information indicating the direction and amount of angular displacement when the FPD 10 is rotated and displaced with respect to the affected area during imaging.

The image reversal information is information indicating the required reversal direction for the radiographic image data. For example, when the subject is exceptionally photographed from the back side and an image from the front side is desired for diagnosis, the front side is selected. This is information indicating the direction of reversal. Since the operator can freely rotate and flip the radiation image data being displayed by inputting operations to the operation unit 22 of the portable terminal 20, the operator can check the radiation image after rotation and flipping, and perform step S8. Image rotation information and image reversal information can be input.

Patient information is information about the subject's patient. The text information is information freely written by the operator. For example, information indicating that the right hand was instructed to be photographed but the left hand was mistakenly photographed; This is information indicating that the image has also been captured. The operator information is information such as the operator's ID and name.

Then, the control unit 21 of the portable terminal 20 transmits the incidental information input in step S8 to the FPD 10 via the wireless communication unit 25 in association with the image ID received in step S6 (step S9). The control unit 11 of the FPD 10 receives the image ID and additional information from the mobile terminal 20 via the wireless communication unit 15 .

In the portable terminal 20, the state information, image ID, radiographic image data, and incidental information are only temporarily stored in the RAM of the control unit 21 and are not stored in the storage unit 23 in steps S3 to S9. This is to prevent leakage of information identifying a patient, such as radiation image data and incidental information. Further, after execution of step S9, the configuration may be such that the status information, radiation image data, additional information, etc. temporarily stored in the RAM of the control unit 21 are deleted. In this configuration, the portable terminal 20 acquires status information and radiographic image data from the FPD 10 each time radiography is performed. Further, the control unit 21 may request the FPD 10 for the erased state information, radiographic image data, additional information, etc., and acquire them from the FPD 10 in accordance with operation information from the operator via the operation unit 22 .

Then, the control unit 11 of the FPD 10 stores the incidental information received in step S9 in the storage unit 13 in association with the image ID of the radiation image data stored in step S5 (step S10). Then, the operator determines whether or not to end radiation imaging (step S11). If radiation imaging is not to be ended (step S11; NO), the process proceeds to step S3.

When radiation imaging is to be terminated (step S11; YES), the operator brings the FPD 10 after imaging into the imaging room and connects it to the cradle 50, and the controller 11 of the FPD 10 switches from memory mode to normal mode. Then, the control unit 41 of the imaging control device 40 establishes a communication connection with the FPD 10 via the wired communication unit 45 (step S12).

Then, the control unit 11 of the FPD 10 reads all image IDs, radiographic image data, and incidental information taken from the storage unit 13, and transmits them to the imaging control device 40 via the wired communication unit 16 (step S13). The control unit 41 of the imaging control device 40 receives all image IDs, radiation image data, and incidental information from the FPD 10 via the wired communication unit 45 .

Then, the control unit 41 of the imaging control device 40 displays the image ID, the radiation image data, and the incidental information received in step S13 on the display unit 44, and stores them in the storage unit 43 (step S14). In step S14, for example, the control unit 41 displays the thumbnail of the radiation image data for each image ID and the icon indicating that the radiation image data is defective when there is the radiation image data identification information, based on the delimiter identification information. A screen UI that is displayed for each patient group, and can freely select and display radiation image data and incidental information in accordance with operation input such as thumbnail or icon click input from the operator via the operation unit 42. (User Interface).

Then, the control unit 41 of the imaging control device 40 transmits storage completion information to the FPD 10 via the wired communication unit 45 to the effect that storage of the image ID, the radiation image data, and the incidental information in the storage unit 43 is completed in step S14. (Step S15). Then, the control unit 11 of the FPD 10 erases the radiation image data and accompanying information transmitted in step S13 from the storage unit 43 (step S16).

After erasing the radiation image data and incidental information from the FPD 10, the control unit 41 of the imaging control device 40 deletes the radiation image data stored in the storage unit 43 according to the operation information input by the operator via the operation unit 42. image adjustment. Image adjustment is performed, for example, by performing image processing for making diagnostic radiographic image data on the radiographic image data, superimposing various markers, and adjusting image rotation information and image reversal information of supplementary information. It includes image processing such as rotation and inversion. The control unit 41 of the imaging control device 40 transmits the radiation image data after image adjustment, the image ID, and the incidental information to the image management server via the communication unit 46 to store them.

As described above, according to the present embodiment, the medical imaging system 1 includes the FPD 10 and the mobile terminal 20 communicatively connected to the FPD 10 . The FPD 10 has a radiation imaging unit 14 that generates radiation image data from incident radiation, and a storage unit 13 that stores the generated radiation image data. The mobile terminal 20 has an operation unit 22 that receives operation input of accompanying information corresponding to generated radiation image data, and a control unit 21 that transmits the operation-inputted accompanying information to the FPD 10 . The FPD 10 has a control unit 11 that receives additional information and stores the additional information in the storage unit 13 in association with the stored radiation image data.

Therefore, by operating the mobile terminal 20, it is possible to easily generate supplementary information of the radiation image data, and store the radiation image data in association with the supplementary information.

Also, the incidental information includes delimiter identification information for grouping a plurality of radiographic image data. For this reason, since the FPD 10 does not require an operation button or a sensor, it is possible to prevent an increase in the cost of the FPD 10 and prevent the risk of patient mix-up when the accuracy of the sensor cannot be guaranteed. Moreover, since there is no complicated work, a plurality of radiographic image data can be grouped easily and accurately.

The mobile terminal 20 also has a display unit 24 . The control unit 21 receives the generated radiation image data from the FPD 10 and causes the display unit 24 to display it. Therefore, the operator can visually confirm the radiographic image data, and can input appropriate incidental information corresponding to the confirmed radiographic image data.

Further, when radiation image data is generated by the radiation imaging unit 14, the control unit 11 assigns an image ID to the generated radiation image data, and stores the radiation image data in the storage unit 13 in association with the image ID. and transmits the radiation image data and the image ID to the mobile terminal 20 . The control unit 21 receives the radiation image data and the image ID from the FPD 10 and causes the display unit 24 to display the radiation image data. The operation unit 22 receives an operation input of incidental information corresponding to the displayed radiation image data. The control unit 21 transmits to the FPD 10 the incidental information input by operation and the image ID corresponding to the incidental information. The control unit 11 receives the transmitted incidental information and image ID, uses the image ID, associates the incidental information with the stored radiation image data, and stores the incidental information in the storage unit 13 . Therefore, the supplementary information can be accurately associated with the radiation image data and stored.

In addition, the control unit 21 performs at least one of image processing, which depends on the FPD 10 , correction processing, gradation processing, and thinning processing, on the received radiation image data, and causes the display unit 24 to display the data. Therefore, radiation image data subjected to image processing suitable for at least one of the FPD 10 and the portable terminal 20 can be displayed.

Further, the control unit 21 receives device information and state information regarding the FPD 10 from the FPD 10 and causes the display unit 24 to display the information. Therefore, the operator can visually check the device information and status information about the FPD 10, and can operate and input appropriate incidental information corresponding to the checked device information and status information.

In addition, the incidental information includes imaging error identification information indicating whether or not the generated radiographic image data has been rejected, image rotation information indicating the direction and amount of rotation to be applied to the generated radiographic image data, and the generated radiographic image. and image reversal information indicating the direction of reversal to be applied to the data. Therefore, it is possible to generate appropriate incidental information including at least one of the identification information of the shooting failure, the image rotation information, and the image reversal information, which is used in the subsequent steps.

The additional information includes re-imaging identification information indicating that the generated radiation image data is re-imaging, patient information about the patient corresponding to the generated radiation image data, and corresponding to the generated radiation image data. At least one of text information and operator information about an operator corresponding to the generated radiation image data is included. Therefore, it is possible to generate appropriate supplementary information including at least one of re-imaging identification information, patient information, text information, and operator information, which is used in subsequent steps.

The medical imaging system 1 further includes an imaging control device 40 communicatively connected to the FPD 10 . The imaging control device 40 includes a storage unit 43, and a control unit 41 that receives the radiation image data and accompanying information stored in the storage unit 13 from the FPD 10 and stores them in the storage unit 43 after imaging the radiation image data. have. Therefore, the imaging control device 40 can store the radiation image data and the incidental information, and can perform processing such as rotation and inversion on the radiation image data based on the incidental information.

After storing the radiation image data and the additional information in the storage unit 43 , the control unit 41 transmits storage completion information of the storage to the FPD 10 . After receiving the storage completion information, the control unit 11 deletes the stored radiographic image data and accompanying information from the storage unit 13 . Therefore, the radiographic image data and accompanying information can be reliably stored, and the storage capacity of the FPD 10 can be recovered, so that the FPD 10 can be easily used for the next radiographic imaging.

The description in the above embodiment is an example of a suitable medical imaging system according to the present invention, and the present invention is not limited to this.

For example, in the above-described embodiment, the portable terminal 20 is configured to input the delimiter identification information and the like and include it in the incidental information, but the present invention is not limited to this. The control unit 21 of the mobile terminal 20 requests the FPD 10 for the stored image ID, radiation image data, and incidental information via the wireless communication unit 25, receives the received image ID, the radiation image data, and the incidental information from the FPD 10. By displaying the information on the display unit 24, receiving an instruction input for correcting the incidental information such as deleting the section identification information, correcting the incidental information, and transmitting the corrected incidental information to the FPD 10 to overwrite the incidental information may be modified.

In the above-described embodiment, each time the FPD 10 generates one sheet of radiation image data, the portable terminal 20 is configured to input supplementary information corresponding to the one sheet of radiation image data. It is not limited. Each time the FPD 10 generates a plurality of pieces of radiographic image data for each patient or the like, the mobile terminal 20 may be configured to input additional information for the plurality of pieces.

Further, in the above-described embodiment, the incidental information is associated with each radiographic image data, but the present invention is not limited to this. The incidental information may be associated with each other information such as examination.

In addition, the detailed configuration and detailed operation of each part constituting the medical imaging system 1 in the above embodiment can be changed as appropriate without departing from the gist of the present invention.

1 medical imaging system 10 FPD
11 Control unit 12 Operation unit 13 Storage unit 14 Radiation imaging unit 15 Wireless communication unit 16 Wired communication unit 17 Bus 20 Portable terminal 21 Control unit 22 Operation unit 23 Storage unit 24 Display unit 25 Wireless communication unit 26 Bus 30 Rounding car 310 Radiation generation Device 311 Radiation source 312 Exposure switch 320 Radiation generation control device 330 Pocket 40 Imaging control device 41 Control unit 42 Operation unit 43 Storage unit 44 Display unit 45 Wired communication unit 46 Communication unit 47 Bus 50 Cradle

Claims (9)

imaging means for generating radiation image data from incident radiation;
a radiographic imaging apparatus comprising: a first storage unit that stores the generated radiographic image data;
a mobile terminal wirelessly connected to the radiographic imaging device and carried by an operator;
The mobile terminal is
an operation means for receiving an operation input of incidental information corresponding to the generated radiation image data;
and a first control means for transmitting the operationally input additional information to the radiographic imaging apparatus,
The radiographic imaging device,
a second control means for receiving the incidental information and storing the incidental information in the first storage means in association with the stored radiation image data ;
The incidental information includes image rotation information indicating the direction and amount of rotation to be applied to the generated radiographic image data, or image inversion information indicating the direction of inversion to be applied to the generated radiographic image data.
Medical imaging system. imaging means for generating radiation image data from incident radiation;
a radiographic imaging apparatus comprising: a first storage unit that stores the generated radiographic image data;
A mobile terminal that is communicatively connected to the radiographic imaging device,
The mobile terminal is
an operation means for receiving an operation input of incidental information corresponding to the generated radiation image data;
a first control unit that transmits the incidental information that has been operated and input to the radiographic imaging apparatus;
display means;
The radiographic imaging device,
a second control means for receiving the incidental information and storing the incidental information in the first storage means in association with the stored radiation image data;
The first control means receives the generated radiographic image data from the radiographic imaging device and causes the display means to display the data;
the operation means receives an operation input of supplementary information corresponding to the displayed radiation image data ;
The incidental information includes image rotation information indicating the direction and amount of rotation to be applied to the generated radiographic image data, or image inversion information indicating the direction of inversion to be applied to the generated radiographic image data.
Medical imaging system. 3. The medical imaging system according to claim 1, wherein the incidental information includes delimiter identification information for grouping a plurality of radiographic image data. When radiographic image data is generated by the imaging means, the second control means adds image identification information to the generated radiographic image data and associates the radiographic image data with the image identification information. storing in the first storage means, transmitting the radiation image data and the image identification information to the portable terminal;
The first control means receives the radiographic image data and the image identification information from the radiographic imaging device and causes the display means to display the radiographic image data;
The first control means transmits the operationally input additional information and image identification information corresponding to the additional information to the radiographic imaging apparatus,
The second control means receives the transmitted incidental information and image identification information, uses the image identification information to associate the incidental information with the stored radiation image data, and stores the incidental information in the first storage. 3. The medical imaging system according to claim 2, wherein said means stores said information. The first control means subjects the received radiographic image data to at least one of correction processing dependent on the radiographic imaging device, gradation processing, and thinning processing, and outputs the data to the display means. 5. The medical imaging system according to claim 2 or 4, for displaying. 6. The medical imaging system according to claim 2, 4, or 5, wherein said first control means receives information relating to said radiographic imaging device from said radiographic imaging device and displays it on said display means. The supplementary information includes re-imaging identification information indicating that the generated radiographic image data is a re-imaging, patient information related to a patient corresponding to the generated radiographic image data, and the generated radiographic image data. 7. The medical imaging system according to any one of claims 1 to 6 , comprising at least one of corresponding text information and operator information about an operator corresponding to said generated radiation image data. An imaging control device that is communicatively connected to the radiographic imaging device,
The imaging control device is
a second storage means;
a third control means for receiving the radiographic image data and accompanying information stored in the first storage means from the radiographic imaging apparatus and storing the radiographic image data in the second storage means after capturing the radiographic image data; The medical imaging system according to any one of claims 1 to 5, comprising: The third control means, after storing the radiographic image data and the incidental information in the second storage means, transmits storage completion information of the storage to the radiographic imaging apparatus,
9. The medical imaging system according to claim 8 , wherein said second control means deletes said saved radiation image data and incidental information from said first storage means after receiving said saving completion information.

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