JP2005253669A - Medical imaging control device and medical imaging system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the efficiency of a comparative interpretation when performing the comparative interpretation comparing a newly imaged medical image with medical images imaged in the past, case images, and the like in a medical image interpretation device. <P>SOLUTION: This medical imaging control device is provided with an imaging control means 111c controlling the medical imaging device; an image processing means 111d processing newly created first image data by controlling the medical imaging device to image a diagnosis object, and outputting the fist image data to the medical image interpretation device displaying diagnosis images for performing the interpretation; an input means 21 used for inputting an instruction of the start of an examination; and an image server control means 111b responding to the instruction of the start of the examination inputted using the input means and controlling an image server which stores second image data expressing the diagnosis images different from the first image data, to deliver the second image data to the medical image interpretation device. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a medical image photographing control apparatus that controls photographing for diagnostic purposes and processes or displays image data obtained by photographing to display or output a medical diagnostic image. Furthermore, the present invention relates to a medical image photographing system configured by such a medical image photographing control device, an image server that records image data, and the like.

  Conventionally, imaging methods using radiation (X-rays, α-rays, β-rays, γ-rays, electron beams, ultraviolet rays, etc.) have been used in various fields, and especially in the medical field, it is the most important for diagnosis. It has become one of the means. Since the first X-ray photography was realized, the X-ray photography method has been improved many times, and at present, a method combining a fluorescent screen and an X-ray film has become mainstream. On the other hand, in recent years, various digitized apparatuses such as X-ray CT, ultrasound, and MRI have been put into practical use, and the construction of diagnostic information processing systems and the like in hospitals is being promoted. Much research has been done to digitize X-ray images, but a radiographic method using a stimulable phosphor has been established and is attracting attention as a replacement for conventional X-ray photography.

  A stimulable phosphor (storable phosphor) is a part of its radiation energy that is stored when irradiated with radiation. After that, when it is irradiated with excitation light such as visible light, it emits light according to the stored energy. It has been known for a long time. A radiographic method using this is to capture and record a radiographic image of a subject such as a human body on a sheet coated with a photostimulable phosphor using an image taking device, and use the image reading device to capture the photostimulable fluorescence. When the body sheet is scanned with excitation light such as laser light, stimulated emission light is generated. Image data is obtained by photoelectrically reading this light. Furthermore, after appropriately processing this image data using an image processing apparatus, the image data can be output to a display such as a CRT, or printed on a film by a laser printer or the like to display a radiation image as a visible image.

  Such a radiographic method has performance comparable to that of a conventional X-ray photography method in terms of imaging sensitivity and image quality. For example, compared with the conventional X-ray photography method, the exposure area is extremely wide, and the response of the photostimulated light to the exposure amount is almost proportional over the entire exposure area. For this reason, no matter what radiation dose the subject is photographed, it is possible to capture the emission region where the image exists and normalize it into a digital signal without excess or deficiency. Further, by combining the signal obtained in this way with an appropriate image processing method, it is possible to provide a steady and high-quality image even under various shooting conditions. Furthermore, since the digitized image information is obtained directly, it is possible not only to store a large amount of data for a long period of time without causing deterioration in image quality, but also to develop into a medical diagnosis information system. Become.

  Usually, radiographic imaging and recording and image processing are performed by a radiologist, and the radiographic image is referred to and interpreted by a doctor. For this reason, image processing of a radiographic image is performed using an image processing apparatus, reference and interpretation of a radiographic image is performed using an image interpretation apparatus, and image data obtained in the image processing apparatus is imaged from the image processing apparatus. Output to the image interpretation device.

  In referring to and interpreting a radiographic image, a newly captured image may be compared with an image captured in the past, a case image, or the like. Conventionally, each time an image to be compared is referred to, a doctor inputs a command to the image interpretation device so that the image stored in the image server is searched and the image to be compared is read each time. Therefore, there is a problem that the comparative interpretation cannot be performed during the period when the image data is acquired from the image server, and the acquisition time is long and the efficiency of the comparative interpretation is poor because the size of the image data is large.

Next, an examination procedure in the conventional medical image photographing system will be described with reference to FIG. FIG. 5 is a flowchart showing an examination procedure in a conventional medical image photographing system.
As shown in FIG. 5, in the conventional medical image photographing system, when the examination is started, the medical image photographing control device controls the medical image photographing device to perform photographing, and image data is generated. The generated image data is input to the medical image photographing control device. After completion of the examination, the medical image photographing control device delivers the image data subjected to predetermined processing to the medical image interpretation device and the image server. The medical image interpretation apparatus stores image data, and the image server records image data.

  In the medical image interpretation apparatus, a medical image newly photographed based on the image data delivered from the medical image photographing control apparatus is displayed, and interpretation is started. Here, when performing a comparative interpretation of comparing a newly captured medical image with a medical image or a case image captured in the past, the operator operates the medical image interpretation apparatus to The image server requests delivery of past image data and the like, and the image server reads the past image data and delivers it to the medical image interpretation apparatus. Then, in the medical image interpretation apparatus, a newly taken medical image and a medical image taken in the past are displayed and comparative interpretation is performed.

  As described above, reading of the image data is started based on the timing of performing the comparative interpretation. Therefore, the comparative interpretation cannot be performed during the period when the image data is acquired from the image server, and the size of the image data Since the acquisition time is long because of the large size, there is a problem that the efficiency of comparative interpretation is poor.

As a related technique, in Patent Document 1 below, a medical image taken on the day is delivered in advance from the host to the terminal, and past images of the same patient that are highly likely to be referred to are delivered to search the image. An automatic reference image delivery system that shortens the time required for the above is disclosed. According to this automatic delivery system, when the host computer receives the day-taken image from the image input terminal, the host computer delivers the day-taken image and the past shot image of the target patient to the requesting image display terminal. By the time you return to the doctor's office from the radiology department or other department, you will be able to finish the normal delivery of the images on the day and past, and even if you need to compare the progress of the medical condition from the previous visit, It is possible to display past images. However, if the size of the captured image is large, if there are many past captured images, or if the distance between the imaging department and the examination room is short, delivery of the photographed image before the patient returns to the doctor's office May not have finished.
JP-A-6-62404 (pages 1, 3 and 1)

  Therefore, in view of the above points, the present invention provides a comparative image interpretation in the case of performing a comparative image comparison in which a newly captured medical image is compared with a medical image or a case image captured in the past. The purpose is to improve the efficiency.

  In order to solve the above problem, a medical image photographing control device according to one aspect of the present invention includes photographing control means for controlling a medical image photographing device and photographing for diagnostic purposes by controlling the medical image photographing device. An image processing means for outputting the first image data and an instruction to start examination are input to a medical image interpretation apparatus that processes the newly generated first image data and displays a diagnostic image for interpretation. And an image server storing second image data representing a diagnostic image different from the first image data in response to an instruction to start examination input using the input means On the other hand, image server control means for controlling to deliver the second image data to the medical image interpretation apparatus is provided.

  In addition, a medical imaging system according to one aspect of the present invention reads a radiographic image newly taken by a medical imaging apparatus that irradiates a subject with radiation and captures a radiographic image, and a medical imaging apparatus. A medical image reading device for generating first image data, an image server for recording second image data generated by reading a radiographic image taken in the past, and first and second image data A medical image interpretation device that displays a diagnostic image based on the image data, and controls the image server to deliver the second image data to the medical image interpretation device in response to the inputted instruction to start examination, The image photographing device is controlled to perform new photographing, the first image data generated by the medical image reading device is processed, and the first image data is output to the medical image interpretation device. Comprising the use imaging control device.

  According to one aspect of the present invention, second image data representing a diagnostic image different from the first image data is stored in response to an examination start instruction input using the input unit. Since the image server is controlled so as to deliver the second image data to the medical image interpretation apparatus, the medical image interpretation apparatus uses a newly captured medical image, a medical image or a case image captured in the past, etc. The efficiency of comparative interpretation can be improved when comparative interpretation is performed.

Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. The same constituent elements are denoted by the same reference numerals, and the description thereof is omitted.
FIG. 1 is a block diagram showing a configuration of a medical image photographing system according to an embodiment of the present invention. As shown in FIG. 1, in the radiology department, a medical image photographing apparatus 10 that records a radiation image on a recording sheet (stimulable phosphor sheet) 1 by irradiating a subject with radiation and photographing, A medical image reading control device 20 is connected to a medical image shooting control device 20 for controlling the medical image shooting device 10, and further, information such as a radiographic image recorded on the recording sheet 1 is photoelectrically read to generate image data. An apparatus 30 and a medical image interpretation apparatus 40 that displays a radiographic image and is used for interpretation are connected to the medical image capturing control apparatus 20 via a network.

  In the radiology department, a medical image interpretation apparatus 40 that displays a radiographic image to be interpreted, an image server 50 that records image data processed by the medical image capturing control apparatus 20 and image supplementary information, and a radiographic image A printer 60 that prints images on a film, an RIS 70 that manages the execution of various tasks related to radiography, and a reception terminal 80 are connected to the medical imaging control apparatus 20 via a network. The RIS 70 is connected to the HIS 90 that manages the operations of the entire hospital and the reception terminal 100 of the hospital via a network.

  A recording sheet 1 used for radiography is coated with a stimulable phosphor material, and information on an object is recorded by irradiation with radiation. In the medical image photographing apparatus 10, the subject is radiographed under predetermined photographing conditions, and the radiographic image is recorded on the recording sheet 1.

  The medical imaging apparatus 10 includes an imaging position raising / lowering mechanism 11 that moves the position of the recording sheet 1 set at a predetermined position up and down to finely adjust the imaging position of the subject, and a subject's position. An imaging table 12 for determining the position of the foot, a radiation generating unit 13 for irradiating the subject with radiation, and an interface 14 for receiving a control signal from the medical imaging control device 20 are included.

  The medical image photographing control device 20 is a console for controlling the medical image photographing device 10, and is attached to an input unit 21 used for inputting examination information and various commands and a cassette for storing the recording sheet 1. It includes a bar code reader 22 that reads a bar code, a display unit 23 that displays an examination, a radiographic image, and the like corresponding to an inputted examination request signal, and a processing unit 110. The processing unit 110 controls the medical image photographing apparatus 10 based on the examination request signal transmitted from the RIS 70 or the like. The processing unit 110 also performs various processes on the image data and the like input from the medical image reading device 30, and transfers the image data and the like to a recording device such as the image server 50 and an output device such as the printer 60. .

  In the present embodiment, in the medical image interpretation apparatus 40, when a radiographic image (current image) newly captured and a radiographic image (past image) captured in the past are comparatively interpreted, the medical image interpretation device 40 was captured in the past. The processing unit 110 of the medical image capturing control device 20 starts an examination in order to deliver image data representing a comparison target image such as a radiation image or a case image of the same patient from the image server 50 to the medical image interpretation device 40 in advance. In response to this instruction, the image server 50 is controlled to deliver the image data to the medical image interpretation apparatus 40 at an early stage in the examination.

  The medical image reading device 30 scans the surface of the recording sheet 1 set at a predetermined position by a light beam emitted from the laser light source 31 and passed through the light scanning unit 32. By this scanning, a light beam is irradiated onto the recording sheet 1, and an amount of stimulated emission light corresponding to the radiation image information accumulated and recorded is generated from the portion irradiated with the light beam. The stimulated emission light is photoelectrically detected by a photomultiplier (photomultiplier tube) 33, output as an analog signal, amplified by an amplifier 34, and digitized by an A / D converter 35.

  Further, the barcode attached to the cassette storing the recording sheet 1 is read by the barcode reader 36, and the read barcode information is used as image supplementary information corresponding to patient information and examination information. The image data and the image supplementary information generated in this way are transmitted from the output unit 37 to the medical image capturing control device 20 via the network.

  The medical image interpretation apparatus 40 includes an input unit 41 that is used to input various commands and the like, a display unit 42 that displays a radiation image and the like, and a processing unit 120. The medical image interpretation apparatus 40 displays a radiation image on the display unit 42 based on the image data delivered from the medical image photographing control apparatus 20 and / or the image server 50. The image server 50 records the image data and image supplementary information delivered from the medical image capturing control device 20 and delivers the image data to the medical image interpretation device 40. The printer 60 prints a medical image on a film or the like based on the image data delivered from the medical image photographing control device 20.

  The RIS 70 functions as an ordering device by transmitting an examination request signal, patient information, and examination information to the medical image radiographing control apparatus 20 in order to start an examination. Similarly, the HIS 90 can function as an ordering apparatus based on an electronic medical record DB (data base) 91. In addition, an ordering apparatus that operates according to a specially developed application program may be provided separately.

  The reception terminal 100 is used to input patient information such as the name and patient ID of a patient who is a subject at the reception of a hospital. It is used for inputting examination information such as an imaging menu representing an area, an examination number, and an examination date. Patient information and examination information may be input using the input unit 21 of the medical image capturing control device 20 or the radiology reception terminal 80. In the electronic medical record DB 91, patient information, examination information, and the like input using the reception terminal 80 or 100 are registered.

  In the present embodiment, even if the medical image interpretation device 40 does not request delivery of image data, the medical image photographing control device 20 represents a comparison target image to the medical image interpretation device 40 in response to an instruction to start an examination. By controlling the image server 50 to deliver the image data, the delivery of the image data is started earlier, and the delivery is surely terminated before the comparative image interpretation in the medical image interpretation apparatus 40 is performed. As a result, the comparison target image can be displayed immediately when performing the comparative interpretation of the current image and the comparison target image, so that the efficiency of the comparative interpretation can be improved.

  FIG. 2 is a block diagram showing a detailed configuration of the medical image photographing control apparatus shown in FIG. The processing unit 110 of the medical image capturing control apparatus includes a central processing unit (hereinafter referred to as a CPU) 111, a memory 112 that temporarily stores input image data, an inspection request signal, and the like, and a hard disk 113 as a recording medium. The hard disk control unit 114 and the network interface 115 are included. These units 111 to 115 are connected to each other via a bus line. Further, the processing unit 110 includes interfaces 116 and 117.

  The memory 112 temporarily stores the inspection request signal received from the ordering device, the barcode information read using the barcode reader 22, and the image data and image supplementary information received from the medical image reading device 30. Remember. The CPU 111 is connected to an input unit 21 such as a keyboard and a mouse and a display unit 23 such as a CRT display via an interface 116, and is connected to the medical image photographing apparatus 10 via an interface 117, and is connected to a network. 1 is connected to the medical image reading device 30, the medical image interpretation device 40, the image server 50, the printer 60, the RIS 70, and the reception terminal 80 shown in FIG.

  The hard disk 113 stores software (program) for causing the CPU 111 to perform an operation. In addition to the built-in hard disk 113, an external hard disk, flexible disk, MO, MT, RAM, CD-ROM, DVD-ROM, or the like can be used as the recording medium.

Next, functional blocks 111a to 111e configured by the CPU 111 and software (program) will be described.
Based on the examination request signal stored in the memory 112, the examination request signal processing unit 111a reads out patient information and examination information corresponding to the examination request signal from the memory 112 and outputs them. The patient information and examination information corresponding to the examination request signal are input from the ordering apparatus together with the examination request signal. The patient information and the examination information output from the examination request signal processing unit 111a are supplied from the output unit 111e to the display unit 23 through the interface 116, and the examination information representing the examination for which the examination start request is issued in the display unit 23. Is displayed.

  When an instruction to start an examination is input using the input unit 21 by an operator who has confirmed the examination information displayed on the display unit 23, the image delivery request signal generation unit 111b displays patient information and examination information corresponding to the examination. And an image delivery request signal is output to the image server 50 via the network interface 115. According to the present embodiment, the image delivery request signal generation unit 111b uses the image delivery request signal so that the image data representing the comparison target image is delivered to the medical image interpretation device 40 in response to the instruction to start the examination. By controlling the image server 50, the delivery of the image data representing the comparison target image is started earlier, and the delivery is surely terminated before the comparative interpretation of the current image and the comparison target image is performed. Yes.

  The imaging control unit 111c captures the medical image via the interface 117 so as to start the examination based on the patient information and the examination information corresponding to the examination for which the operator inputs the examination start instruction using the input unit 21. The apparatus 10 is controlled. Further, the barcode attached to the cassette for storing the recording sheet used for photographing is read by the barcode reader 22 to generate barcode information. The imaging control unit 111c stores the patient information and examination information regarding the examination to be started and the generated barcode information in the memory 112 in association with each other.

  The image processing unit 111d performs necessary image processing on the image data received from the medical image reading device 30. The image data subjected to the necessary image processing is supplied from the output unit 111e to the display unit 23 via the interface 116, and an image is displayed on the display unit 23, and the image is confirmed by the operator. Further, the image data on which necessary image processing has been performed is stored in the memory 112 and is recorded on the hard disk 113 via the hard disk control unit 114 or medical image interpretation via the network interface 115 in accordance with an instruction from the operator. Delivered to the device 40, the image server 50, or the like.

  In this embodiment, the inspection request signal processing unit 111a, the image delivery request signal generation unit 111b, the imaging control unit 111c, the image processing unit 111d, and the output unit 111e are configured by a CPU and software. Or an analog circuit.

  FIG. 3 is a block diagram showing a detailed configuration of the medical image interpretation apparatus shown in FIG. The processing unit 120 of the medical image interpretation apparatus includes a CPU 121, a memory 122 that temporarily stores input image data, a hard disk 123 as a recording medium, a hard disk control unit 124, a network interface 125, and an interface 126. Is included. Each part 121-125 is mutually connected via the bus line.

  The CPU 121 is connected to the medical image capturing control device 20 and the image server 50 shown in FIG. Further, the CPU 121 is connected to an input unit 31 such as a keyboard and a mouse and a display unit 42 such as a CRT display via an interface 126. The memory 122 temporarily stores the image data output from the medical image capturing control device 20 and the image data output from the image server 50.

  The hard disk 123 stores software (program) for causing the CPU 121 to perform an operation. In addition to the built-in hard disk 123, an external hard disk, flexible disk, MO, MT, RAM, CD-ROM, DVD-ROM, or the like can be used as the recording medium.

Next, functional blocks 121b to 121c configured by the CPU 121 and software (program) will be described.
The interpretation image processing unit 121a generates image data for displaying the current image based on the image data input from the medical image capturing control device 20, or the image data input from the medical image capturing control device 20 And image data input from the image server 50, image data for displaying the current image and the comparison target image side by side is generated, and the image data is output from the output unit 121 c to the display unit 42 via the interface 126. Supply. The display unit 42 displays a diagnostic image based on the image data.

  Alternatively, the difference processing unit 121b performs difference processing (subtraction) on the image data input from the medical image capturing control device 20 and the image data input from the image server 50 to obtain difference image data. The interpretation image processing unit 121a supplies the difference image data obtained in the difference processing unit 121b from the output unit 121c to the display unit 42 via the interface 126. The display unit 42 displays a diagnostic image based on the difference image data.

  In the present embodiment, the interpretation image processing unit 121a, the difference processing unit 121b, and the output unit 121c are configured by a CPU and software, but may be configured by a digital circuit or an analog circuit.

  Next, an examination procedure in the medical image photographing system according to the present embodiment will be described with reference to FIGS. FIG. 4 is a flowchart showing an examination procedure in the medical image photographing system.

  As shown in FIG. 4, first, in step S11, the examination request signal processing unit 111a of the medical imaging control apparatus 20 outputs patient information and examination information to the output unit 111e and the interface based on the inputted examination request signal. The information is output to the display unit 23 via 116, and the display unit 23 displays the examination information indicating the examination for which the examination start request is issued. The inspection information displayed on the display unit 23 is confirmed by the operator.

  The operator who has confirmed the examination information displayed on the display unit 23 uses the input unit 21 to input an instruction to start the examination. In step S12, when an instruction to start examination is input to the image delivery request signal generation unit 111b, in step S13, the image delivery request signal generation unit 111b includes an image including patient information and examination information corresponding to the examination request signal. A delivery request signal is generated, and this image delivery request signal is output to the image server 50. When there are a plurality of image servers, an image delivery request signal is output to a predetermined image server based on the name of the image delivery destination image server included in the examination information or the like.

  When the image delivery request signal is input, the image server 50 obtains medical image data representing a past image of the same patient or image data representing a case image based on the input image delivery request signal in step S31. Delivered to the image interpretation device 40. For example, the image server 50 searches for radiation images taken in the past of the same patient based on the patient name of the patient information included in the image delivery request signal, and also based on the imaging part of the examination information. Then, the case images of the same imaging region are searched, and image data representing these images is delivered to the medical image interpretation device 40. When there are a plurality of medical image interpretation apparatuses, the image data is delivered to the medical image interpretation apparatus operated by the interpretation doctor based on the name of the interpretation doctor in the examination information. The image data delivered from the image server 50 is stored in the memory 122 of the medical image interpretation apparatus 40 in step S21.

  When the operator reads the barcode attached to the cassette that stores the recording sheet used for photographing using the barcode reader 22 of the medical image photographing control device 20, in step S14, the medical image photographing control device 20 displays the barcode. The barcode information generated by reading the code is stored in the memory 112 in association with the inspection information.

  Next, when the operator sets a cassette at a predetermined position of the medical image photographing apparatus 10 and inputs an instruction to start photographing for starting photographing using the input unit 21, in step S15, the photographing control unit 111c. However, the medical image photographing apparatus 10 is controlled so as to start photographing based on the patient information and examination information corresponding to the examination to be photographed.

  In step S <b> 16, the medical image photographing control device 20 stores image data representing the current image read by the medical image reading device 30 after photographing in the memory 112. In step S <b> 17, the image processing unit 111 d performs predetermined image processing on the image data representing the current image stored in the memory 112. Note that the type of image processing may be specified by the image processing unit 111d displaying a radiographic image on the display unit 23 based on the image data, and an operator confirming the radiographic image using the input unit 21.

  After predetermined image processing is performed on the image data representing the current image, the operator inputs a delivery command for delivering the image data representing the current image using the input unit 21, whereby image processing is performed in step S <b> 18. The unit 111d transfers image data representing the current image subjected to predetermined image processing to the medical image interpretation apparatus 40 and the image server 50 via the network interface 115.

  In step S22, the medical image interpretation apparatus 40 stores the received image data representing the current image in the memory 122, and in step S32, the image server 50 records the received image data representing the current image.

  In step S <b> 23, the interpretation image processing unit 121 a of the medical image interpretation apparatus 40 displays the current image on the display unit 42 based on the image data representing the current image stored in the memory 122.

  When an operator who has confirmed the current image displayed on the display unit 42 inputs a comparative interpretation start command for starting comparative interpretation using the input unit 41, in step S24, the comparative interpretation start command is processed by the interpretation image processing. In step S25, the interpretation image processing unit 121a performs comparison interpretation on the display unit 42 based on the image data representing the current image and the image data representing the comparison target image stored in the memory 122. Display an image.

  The comparative interpretation image may be an image in which the current image and the comparison target image are arranged, or the interpretation image processing unit 121a performs difference processing on the image data representing the current image and the image data representing the comparison target image. It may be an image. Note that an operator such as a doctor can specify whether to display the arranged images or to display the image subjected to the difference processing by using the input unit 41.

  In the present embodiment, the medical image capturing control device 20 controls the image server 50 to deliver image data representing the comparison target image to the medical image interpretation device 40 at the start of the examination. The imaging control device 20 transmits a notification of examination start to the medical image interpretation device 40 at the start of examination, and the medical image interpretation device 40 responds to the notification of examination start and outputs image data representing the comparison target image. The image server 50 may be controlled so as to be delivered to the medical image interpretation apparatus 40.

  Alternatively, when the ordering apparatus transmits the examination request signal to the medical image capturing control apparatus 20, the ordering apparatus may control the image server 50 to deliver the image data representing the comparison target image to the medical image interpretation apparatus 40. good. Further, when the ordering apparatus transmits an examination request signal to the medical image capturing control apparatus 20, the image server 50 is configured to deliver image data representing past images of the same patient to the medical image capturing control apparatus 20. By controlling, it is possible to confirm the imaging conditions and the like when imaging was performed in the past in the medical image imaging control device 20, so that it can be used as a reference when setting imaging conditions such as positioning and dose.

  The present invention includes a medical image photographing control device that controls imaging for diagnostic purposes and processes or displays image data obtained by imaging to display or output a medical diagnostic image, an image server that records image data, and the like. It can be used in a medical image photographing system.

It is a block diagram which shows the structure of the medical image imaging system which concerns on one Embodiment of this invention. It is a block diagram which shows the detailed structure of the medical image imaging control apparatus shown in FIG. It is a block diagram which shows the detailed structure of the medical image interpretation apparatus shown in FIG. It is a flowchart which shows the test | inspection procedure in the medical image imaging system which concerns on one Embodiment of this invention. It is a flowchart which shows the test | inspection procedure in the conventional medical image imaging system.

Explanation of symbols

1 Recording sheet (stimulable phosphor sheet)
DESCRIPTION OF SYMBOLS 10 Medical imaging device 11 Imaging position raising / lowering mechanism 12 Imaging stand 13 Radiation generation part 14 Interface 20 Medical imaging control apparatus 21 Input part 22 Bar code reader 23 Display part 30 Medical image reading apparatus 31 Laser light source 32 Optical scanning part 33 Photomulti Plier (photomultiplier tube)
34 Amplifier 35 A / D Converter 36 Barcode Reader 37 Output Unit 40 Medical Image Interpreting Device 41 Input Unit 42 Display Unit 50 Image Server 60 Printer 70 RIS
80 reception terminal 90 HIS
91 Electronic Medical Record DB
100 reception terminal 110 processing unit 111 CPU
111a Inspection request signal processing unit 111b Image delivery request signal generation unit 111c Imaging control unit 111d Image processing unit 111e Output unit 112 Memory 113 Hard disk 114 Hard disk control unit 115 Network interface 116, 117 Interface 120 Processing unit 121 CPU
121a Interpretation image processing unit 121b Difference processing unit 121c Output unit 122 Memory 123 Hard disk 124 Hard disk control unit 125 Network interface 126 Interface

Claims (9)

Photographing control means for controlling the medical image photographing device;
The first medical image interpretation apparatus that processes the first image data newly generated by controlling the medical image photographing apparatus and performs photographing for the purpose of diagnosis and displays the diagnostic image for interpretation is provided as a first. Image processing means for outputting image data;
An input means used for inputting an instruction to start an inspection;
In response to the examination start instruction input using the input means, the second image data stored in the second image data representing the diagnostic image different from the first image data is sent to the second image data. Image server control means for controlling image data to be delivered to the medical image interpretation device;
A medical image photographing control apparatus comprising:   The first image data is image data generated by reading a radiographic image newly taken by irradiating a subject with radiation using a medical image reader, and the second image data is The medical image capturing control device according to claim 1, wherein the medical image capturing control device is image data generated by reading a radiation image captured in the past by irradiating the subject with radiation using a medical image reading device.   The medical image photographing control apparatus according to claim 1, wherein the second image data is image data representing a case image.   The medical image according to any one of claims 1 to 3, wherein the second image data is image data generated by imaging the same part as the part represented by the first image data. Shooting control device. A medical imaging device that irradiates a subject with radiation and captures a radiation image;
A medical image reading device for generating first image data by reading a radiographic image newly taken by the medical image taking device;
An image server that records second image data generated by reading a radiation image captured in the past;
A medical image interpretation apparatus for displaying a diagnostic image based on the first and second image data;
In response to the inputted instruction to start the examination, the image server is controlled to deliver the second image data to the medical image interpretation device, and the medical image photographing device is controlled to perform a new photographing. A medical image photographing control device that processes the first image data generated by the medical image reading device and outputs the first image data to the medical image interpretation device;
A medical image photographing system comprising: A medical imaging device that irradiates a subject with radiation and captures a radiation image;
A medical image reading device for generating first image data by reading a radiographic image newly taken by the medical image taking device;
An image server that records second image data generated by reading a radiation image captured in the past;
A medical image interpretation device that controls the image server to deliver second image data in response to a notification of examination start and displays a diagnostic image based on the first and second image data;
In response to the input examination start instruction, a notification of examination start is transmitted to the medical image interpretation device, and the medical image photographing device is controlled to perform a new photographing and is generated by the medical image reading device. A medical image photographing control device that processes the first image data and outputs the first image data to the medical image interpretation device;
A medical image photographing system comprising: A medical imaging device that irradiates a subject with radiation and captures a radiation image;
A medical image reading device for generating first image data by reading a radiographic image newly taken by the medical image taking device;
An image server that records second image data generated by reading a radiation image captured in the past;
A medical image interpretation apparatus for displaying a diagnostic image based on the first and second image data;
Based on the examination request signal, the medical image photographing device is controlled to perform new photographing, the first image data generated by the medical image reading device is processed, and the first image is transmitted to the medical image interpretation device. A medical imaging control device for outputting data;
An ordering device that transmits an examination request signal to the medical image capturing control device and controls the image server to deliver second image data to the medical image interpretation device;
A medical image photographing system comprising:   The medical image according to any one of claims 5 to 7, wherein the medical image interpretation apparatus displays a radiographic image corresponding to the first image data and a radiographic image corresponding to the second image data side by side. Shooting system.   The medical image interpretation apparatus displays an image based on image data obtained by performing a difference process on the first image data and the second image data. Medical imaging system.

Images