JP3403144B2 - X-ray diagnostic system - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an X-ray CT apparatus, X
The present invention relates to an X-ray diagnostic system such as an X-ray diagnostic apparatus.

[0002]

2. Description of the Related Art Conventionally, image diagnostic apparatuses such as an X-ray CT apparatus, an X-ray diagnostic apparatus, an MRI apparatus and a SPECT apparatus have been known. These image diagnostic apparatuses are composed of a plurality of units such as a scanner body, a bed, a high-voltage generator, a console, and an imager, and are designed and manufactured assuming that these units are arranged adjacent to each other. It had been. Table 1 shows an example of the size of each unit of an X-ray CT apparatus, which is a type of image diagnostic apparatus. Table 1 Width Depth Weight Scanner Main Body 2200mm 1000mm 1400kg Bed 700mm 2300mm 300kg High Pressure Generator 600mm 400mm 250kg Console 1300mm 900mm 250kg Imager 600mm 800mm 150kg Next, we will explain each unit in detail with an X-ray CT system as an example. FIG. 8 shows a configuration diagram of a conventional X-ray CT apparatus. The scanner body 101 includes an X-ray tube 105 and a detector 106,
It is composed of the DAS 107. The image processing unit 102 uses C
PU109, reconstruction device 110, image processing device 111,
The storage device 112 is included. High voltage generator 103
Generates a high voltage to be supplied to the X-ray tube 105. The bed 104 is for moving the subject M on it. The detector 106 detects a transmitted X-ray of the subject. The DAS 107 converts the X-ray detection signal detected by the detector 106 into a digital signal. The operation unit 108 is an operation panel for performing various operations of the X-ray CT apparatus. The CPU 109 generates a control signal for controlling each part.

The image reconstruction device 110 reconstructs an image from the projection data detected by the detector 106.
The image processing device 111 performs image processing such as scaling and moving of the image reconstructed by the image reconstructing device 110. The storage device 112 stores the projection data sent from the DAS 107, the image reconstructed by the image reconstructing device 110, or the image processed by the image processing device 111. The display device 113 displays the image signal sent through the image processing device 111. The imager 114 prints an image sent as an image signal on a film. Conventional X-ray C
In the T apparatus, the CPU 109 controls the scanner main body 101, the image reconstruction apparatus 110, the image processing apparatus 111.
It was not possible to operate each unit independently because it was controlling.

[0004]

Conventionally, most of the time, a diagnostic image was observed on the spot by an image diagnostic apparatus such as an X-ray CT apparatus. However, with the advent of advanced image processing methods and diagnostic methods, the method of handling diagnostic images obtained from an image diagnostic apparatus is also diversifying significantly. Therefore, the present invention is
It is an object of the present invention to provide an X-ray diagnostic system which can easily realize various image processing methods and diagnostic methods.

[0005]

In order to achieve the above object, the present invention detects an X-ray source that irradiates an object placed on a bed with X-rays and an X-ray that has passed through the object. And a photographing device having a storage unit for storing raw data obtained by the detector, and an image generating means which is a separate body from the photographing device and generates an image based on the raw data. And an image generation device having a communication means for allowing the raw data and the configuration data including the number of channels or radius of the detector to be communicated between the imaging device and the image generation device. It is characterized by that.

According to the present invention, the photographing device and the image generating device are separate bodies, and the raw data obtained by the photographing device is transmitted to the image generating device through the communication means. As a result, the image capturing apparatus does not have to have the image generation function, so that the installation space of the apparatus can be reduced. Further, by making the configuration data including the data about the number of channels or the radius of the detector of the image capturing apparatus communicable between the image capturing apparatus and the image generating apparatus, an image can be generated by the image generating apparatus regardless of the image capturing apparatus. Further, the image generating device can generate an image based on the raw data transmitted from the photographing device as needed. With this, even if the image capturing apparatus does not have an advanced image processing method, the image generating apparatus capable of performing the image processing method may be used, so that it is possible to cope with the advanced image processing method without purchasing a new apparatus. . Further, since only the photographing device can be operated, it is possible to use a place with a small installation space such as a medical examination car.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION X of the first embodiment according to the present invention
The line diagnostic system will be described. FIG. 3 is a configuration diagram of the scan unit (data detection unit) of the X-ray CT apparatus. The scanner body 1 includes an X-ray tube, a detector 3, and a DAS 4. The X-ray tube 6 of the high-voltage generator 6 generates a high voltage to be supplied to the X-ray tube 2. The bed 7 is a table on which the subject M is placed and operated. The detector 3 detects projected X-rays of the subject M. The DAS 4 converts an X-ray detection signal detected by the detector 3 into a digital signal. The storage device 5 stores scan conditions, examination date and time, examination place, patient data, projection data, and the like, and is connected to the DAS 4 and the transmission / reception device 10. The transmission / reception device 10 transmits and receives data by radio waves. The simple operation unit 8 is a simple operation panel for operating the scan unit. The CPU 9 generates a control signal for controlling the scanner unit. Next, the operation of each component of the scanning unit will be described. The subject M on the bed 7 is moved and the imaging position is adjusted. Subject M
After the positioning is completed, the patient data and the scanning conditions are input from the simple operation unit 8 to instruct the start of scanning. CPU
9 sends the patient data, scan conditions, examination date and time, and examination location to the storage device 5. The storage device 5 stores these data. After the storage is completed, the CPU 9 sends a signal for performing a scan to each unit.

When the CPU 9 outputs a scan start signal, each section operates as follows. The high voltage generator 6 is
A high voltage is generated and supplied to the X-ray tube 2. The X-ray tube 2 generates X-rays by the high voltage from the high-voltage generator 6 and irradiates the subject M with the X-rays. The detector 3 detects the amount of transmitted X-rays that have passed through the subject M at this time and sends it to the DAS 4. DAS4
Converts the signal sent from the detector 3 into a digital signal and sends it to the storage device 5. The storage device 5 stores the digital signal from the DAS 4. The X-ray tube 2 and the detector 3
Detects a transmitted X-ray while rotating around the subject M by a rotating mechanism (not shown). Next, the configuration of the image processing unit will be described. FIG. 2 is a configuration diagram of the image processing unit of the X-ray CT apparatus. The transmitter / receiver 15 transmits and receives data by radio waves. The storage device 16 is
It stores scan conditions, examination date and time, patient data, projection data, and the like, and is connected to the transmitting / receiving device 15 and the image reconstructing device 12. The CPU 11 controls each unit of the image processing unit. The operation unit 18 is an operation panel for performing various operations of the image processing unit. The image reconstruction device 12 reconstructs an image from projection data, and sends the reconstructed image to the image processing device 13. The image processing device 13 performs image processing such as scaling and ROI (enhancement processing) on the image from the image reconstruction device 12, and sends it to the display device 14 and the imager 17. The display device 14 displays an image sent from the image processing device 13. The imager 17 is a recording device that records an image sent through the image processing device 13 on a film.

Next, the operation of each component of the image processing section will be described. The image reconstruction device 12 reconstructs a tomographic image of the subject M based on the projection data stored in the storage device 16 and sends it to the image processing device 13. The image processing device 13 is C
Image processing is performed based on the operation information of the operation unit 18 sent via the PU 11, and the image processing is sent to the display device 14. Display device 1
4 displays this image. As a result, a tomographic image obtained from the projection data measured by the scanning unit can be displayed on the display device 14. Further, at this time, an arbitrary image displayed by operating the operation unit 18 can be recorded by the imager 17. Next, the data transmission of the scanning unit and the image processing unit will be described. The operation unit 18 of the image processing unit is operated to put the transmission / reception device 15 in a reception standby state. Next, the simple operation unit 8 is operated to instruct the start of transmission. Upon receiving the transmission start signal, the CPU 9 instructs the transmission / reception device 10 of the scanning unit to transmit the calling signal.
When the transceiver 10 receives this signal from the CPU, the transceiver 10 transmits a calling signal including the device identification number of the scanning unit.
The transmitting / receiving device 15 receives the calling signal, compares the device identification number included in the calling signal with a device identification number stored in advance, and if they match, a reception confirmation signal indicating that the calling signal has been received. To send. When receiving the reception confirmation signal, the transmission / reception device 10 sends to the CPU 9 a signal indicating that the reception confirmation signal has been received. This makes it possible to confirm the line to which the data is transmitted.

When the CPU 9 confirms the reception of the reception confirmation signal, the identification number of the scanning unit and the configuration of the scanning unit (X
The data of the number of channels of the line detector, the radius of the detector, etc.) is sent to the transmitter / receiver 10. The transmission / reception device 10 transmits the identification number of the scan unit and the configuration data of the scan unit. After the transmission of the identification number of the scanning unit and the configuration data of the scanning unit is completed, the CPU 9 instructs the storage device 5 and the transmission / reception device 10 to transmit the storage data. The transceiver 10 is a CP
When receiving an instruction to send stored data from U9, scan conditions, patient data, examination date and time stored in the storage device 5,
Data such as inspection location and projection data are read and transmitted. When the transmission of the stored data is completed, the CPU 9 instructs the transmission / reception device 10 to end the transmission. Transceiver 10
When receiving a transmission end instruction, transmits a transmission end signal. The transmission / reception device 15 receives data such as the identification number of the scanning unit, the configuration data of the scanning unit, the scanning conditions, the patient data, the examination date / time, the examination place, and the projection data, which are transmitted from the transmission / reception device 10, and stores the data in the storage device 16. To do. When the transmission / reception device 15 receives the transmission end signal, the transmission / reception device 15 returns to the reception standby state. As a result, data can be transmitted from the scanning unit to the image processing unit. Further, a mechanism for checking whether the transmitted data has been surely received may be provided.

With such a configuration, the X-ray projection data can be measured only by the scanning unit. Further, such a scanning unit may be mounted on a vehicle and used for a group medical examination or the like. In addition, by mounting the scanning unit on the ambulance, the data measured in the ambulance can be transmitted to the image processing unit in the hospital by radio waves to make a diagnosis before the patient arrives. Next, a second embodiment according to the present invention will be described. 1 and 4 are block diagrams of the second embodiment. In the second embodiment, the image reconstruction device 12 is provided in the scanning unit. The configuration of the second embodiment will be described below. Note that the description of the same configuration as the first embodiment is omitted. The image reconstructing device 12 reconstructs a tomographic image from projection data.
It is provided between. The projection data detected by the detector 3 is converted into digital projection data by the DAS 4 and sent to the image reconstruction device 12. The image reconstruction device 12 reconstructs a tomographic image from this projection data and sends the reconstructed image to the storage device 5. The storage device 5 stores this image. Next, similarly to the first embodiment, communication is performed between the transmission / reception device 10 and the transmission / reception device 15, and the data stored in the storage device 5 is transmitted to the storage device 16. That is,
A tomographic image is stored in the storage device 16.

The image processing device 13 applies various image processing to the image stored in the storage device 16 based on the operation of the operation unit 18, converts the image into a video signal, and sends the video signal to the display device 14. The display device 14 displays this video signal as an image.
At this time, an arbitrary image displayed by operating the operation unit 18 can be recorded by the imager 17. With such a configuration, the X-ray projection data can be measured only by the scanning unit, so that the device can be downsized. Next, a third embodiment according to the present invention will be described. FIG. 5 is a configuration diagram of the imaging unit (data detection unit) of the X-ray diagnostic apparatus. The high voltage generator 31 is for generating a high voltage to be supplied to the X-ray tube 30. The bed 34 (not shown) is for placing the subject M thereon. The image intensifier 35 converts the transmitted X-rays transmitted through the subject M into an optical image. The image pickup device 36 converts the optical image converted by the image intensifier 35 into an image signal. The DAS 37 converts an analog image signal output from the image sensor 36 into a digital signal. The storage device 38 stores data. The transmission / reception device 39 transmits and receives data by radio waves. The simple operation unit 33 is
It is a simple operation panel for operating the imaging unit. CPU3
2 generates a control signal for controlling the image pickup unit.

Next, the operation of each component of the photographing section will be described. When patient data and scan conditions are input from the simple operation unit 33 and an instruction to start imaging is given, the CPU 32 stores the scan conditions, patient data, examination date, examination place, and image data in the storage device 38. When the storage of these data is completed, the CPU 32 sends a signal to start photographing to each unit.
When the CPU 32 gives an instruction to start photographing, each unit operates as follows. The high voltage generator 31 generates a high voltage to generate X
Supply to the wire tube 30. The X-ray tube 30 is a high voltage generator 3
The high voltage from 1 generates X-rays and irradiates the subject M. The image intensifier 35 converts the transmitted X-rays transmitted through the subject M into an optical image. Imaging device 36
Converts the optical image converted by the image intensifier 35 into an image signal and sends it to the DAS 37. DAS
37 converts this image signal into a digital signal and sends it to the storage device 38. The storage device 38 stores the digital signal from the DAS 37. Next, similarly to the first embodiment, the data stored in the storage device 38 is transmitted to the storage device 41 of the image processing unit. FIG. 6 is a configuration diagram of the image processing unit of the X-ray diagnostic apparatus. The storage device 41 is the transmission / reception device 4
The signal received at 0 is stored. The image processing device 42 is for performing image processing such as scaling of an image stored in the storage device 41 and ROI. Display device 4
3 is for displaying an image sent through the image processing device 42. The CPU 45 controls each unit of the image processing unit. The operation unit 46 is an operation panel for performing various operations of the image processing unit. The imager 44
It is a recording device for recording an image sent through the image processing device 42 on a film.

Next, the operation of the image processing section will be described.
The data reception is the same as that in the first embodiment, so the description thereof will be omitted. The storage device 41 stores image data captured by the imaging device 36. The image processing device 42 reads the image stored in the storage device 41, performs various image processes based on the operation of the operation unit 46, converts the image into a video signal, and sends the video signal to the display device 43. The display device 43 displays this video signal as an image. As a result, the tomographic image obtained from the projection data measured by the scanning unit can be displayed on the display device 43. Further, any image displayed by operating the operation unit 46 can be recorded by the imager 44. With such a configuration, the apparatus can be downsized because the X-ray projection image can be captured only by the imaging unit. Further, the photographing unit may be mounted on the vehicle as in the first embodiment. Further, since the imaging unit of the X-ray diagnostic apparatus can be made relatively small, it is possible to take an X-ray projection image in each hospital room by making it movable in the hospital. In this case, communication by radio waves makes communication difficult due to obstacles such as walls, so a LAN (local area network) with optical fibers or coaxial cables is provided in the hospital and image transmission is performed using this communication line. You may go.

Next, a fourth embodiment will be described. The description of the same parts as those in the first embodiment will be omitted. In the fourth embodiment, a recording medium is used instead of a communication device to transmit information. The transceiver 10 of FIG. 1 is a data recording device 47 (not shown), and the transceiver 15 of FIG. 2 is a data reading device 48 (not shown). The data recording device 47 is a CPU
The identification number of the scanning unit, the configuration data of the scanning unit, and the scan conditions, patient data, examination date, examination location, projection data, etc. stored in the storage device 5 are recorded on the optical disc. The data reading device 48 reads the data recorded on the optical disc and stores it in the storage device 16. Image reconstruction device 12
Calculates a tomographic image based on the data stored in the storage device 16 and sends it to the image processing device 13. The image processing device 13
The image obtained by the image reconstructing device 12 is subjected to various image processes and displayed on the display device 14. According to such a configuration, the data is stored in the storage medium and moved, so that it can be used even in a place where radio waves are easily disturbed and communication is difficult. Further, the method of using the storage medium as described above can also be used in the second and third embodiments.

Next, a fifth embodiment according to the present invention will be described. In the fifth embodiment, a scan unit according to the present invention and a simple operation unit of an image pickup unit will be described. FIG. 7 shows an embodiment of the simple operation unit. The simple operation unit is composed of a simple display unit 50, an input key 51, a scan start key 52, and an emergency stop switch 53, and is 18 cm (vertical) ×
The size is about 12 cm (width). Simple display unit 50
Is a liquid crystal panel that displays the shooting conditions and the like input from the input keys 51. The input key 51 is 13 push buttons, is composed of 10 keys, # key, * key, and enter key, and is arranged below the simple display unit 50. The scan start key 52 is composed of two push buttons. The emergency stop switch 53 is composed of a slightly larger push button switch so as to be operated immediately in an emergency, and is arranged on the right side of the simple display unit 50. Next, the operation of each unit will be described. The abbreviated number of the preset scanning condition is input with the input key 51. The input abbreviated number is sent to the CPU connected to the simple operation unit. The CPU sets scan conditions (intensity of X-rays, scan speed, scan method, etc.) corresponding to this abbreviated number, and at the same time, sends the data of the abbreviated number and the scan condition to the simple display unit 50. Simple display 5
In 0, the data of the sent scan condition is displayed. For example, if you input "* 1 enter", this input data will be sent to the CPU connected to the simple operation unit, the scan conditions for head diagnosis will be set, and if you input "* 2 enter" Scan conditions for abdominal diagnosis are set.

Next, the patient data is input with the input key 51. The patient data at this time is identification data by numbers such as reference numbers, and is, for example, “# 1 2 3 e
If "enter" is entered, 123 is stored as patient data. Next, in order to instruct the start of scanning, the scan start key 52a provided at the bottom of the simple operation section
And by pressing the scan start key 52b at the same time,
It is possible to instruct the start of the scanning operation. In this way, by making the scan start key a 2-button type,
It is possible to prevent the operator from mistakenly instructing the start of scanning. If an abnormality occurs during the scanning operation, the scanning operation can be stopped by pressing the emergency stop button 53. By using the simple operation unit of the seventh embodiment, the operation unit of the scan unit or the image pickup unit can be downsized. In addition, in the seventh embodiment, as the patient identification data, a number is input from the 10 key, but an alphabet or kana input key is provided,
You may be able to input the name. Also, in order to input scan conditions and patient data more smoothly,
A bar code reader may be provided to input data.

It is needless to say that the present invention is not limited to the above-described embodiment and can be variously modified without departing from the spirit of the invention. In addition, when transmitting data, the data may be compressed using a data compression device or the like before transmission. Further, a configuration may be adopted in which a plurality of scanning units are provided for one image processing unit. In addition to the X-ray CT apparatus and the X-ray diagnostic apparatus, the MRI apparatus and the SPECT apparatus can be used. Furthermore, the type of diagnostic device is added to the device configuration data, and X-ray C
A single image processing apparatus may process different types of diagnostic apparatuses such as a T apparatus, an X-ray diagnostic apparatus, and an MRI apparatus. Further, although radio waves are used for communication in the above-described embodiment, data or images may be transmitted using communication means using satellites, communication means using telephone lines, or communication lines such as optical fibers or coaxial cables. good. Alternatively, the identification number of the scanner to be received may be stored in advance on the image processing apparatus side, and only the data of the scanner having the same identification number may be received.

[0019]

As described above, according to the present invention, an image can be generated by an image generating device regardless of the photographing device while realizing downsizing of the photographing device.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a scanner unit according to a first embodiment of the invention.

FIG. 2 is an explanatory diagram of an image processing unit according to the first embodiment of this invention.

FIG. 3 is an explanatory diagram of a scanner unit according to a second embodiment of the invention.

FIG. 4 is an explanatory diagram of an image processing unit according to a second embodiment of the present invention.

FIG. 5 is an explanatory diagram of an image pickup unit according to a third embodiment of the present invention.

FIG. 6 is an explanatory diagram of an image processing unit according to a third embodiment of the present invention.

FIG. 7 is an explanatory diagram of a simple operation unit according to the present invention.

FIG. 8 is an explanatory diagram of a conventional X-ray CT apparatus.

[Explanation of symbols]

1, 101 Scanner body 3,106 detector 4, 37, 107 DAS 5, 16, 38, 40, 112 Storage device 10, 39, 15, 40 transceiver 8, 18, 33, 46, 108 Operation unit 9, 11, 32, 45, 109 CPU 12,110 Image reconstruction device 13, 42, 111 image processing device 36 Imaging device

─────────────────────────────────────────────────── --- Continuation of the front page (56) Reference JP-A-4-54568 (JP, A) JP-A-4-154334 (JP, A) JP-A-6-277207 (JP, A) JP-A-63- 109843 (JP, A) (58) Fields surveyed (Int.Cl. ⁷ , DB name) A61B 6/00 A61B 6/03

Claims (5)

(57) [Claims] 1. An X-ray source for irradiating a subject placed on a bed with X-rays, a detector for detecting X-rays transmitted through the subject, and raw data obtained by the detector. An image capturing apparatus having a storage unit for storing the image capturing apparatus, and an image generating apparatus which is a separate body from the image capturing apparatus and has image generating means for generating an image based on the raw data, the image capturing apparatus and the image generating unit. An X-ray diagnostic system comprising: a communication unit capable of communicating the raw data and configuration data including data on the number of channels or the radius of the detector with an apparatus. 2. The X-ray diagnostic system according to claim 1, wherein the imaging device transmits the configuration data together with the raw data to the image generation device via the communication means. 3. The X-ray diagnostic system according to claim 1, wherein the imaging device transmits the raw data to the image generating device after transmitting the configuration data. 4. The photographing device, together with the raw data,
It has a first storage means for storing data including any of imaging conditions, patient data, examination date and time, and examination place together with the raw data, and transmits identification information of the photographing apparatus to the image generating apparatus. The X-ray diagnostic system according to any one of claims 1 to 3, wherein the data stored in the first storage unit is transmitted thereafter. 5. The X-ray diagnostic system according to claim 1, wherein the imaging device is mounted on a vehicle.