WO2015166575A1 - 放射線断層撮影装置 - Google Patents
放射線断層撮影装置 Download PDFInfo
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- WO2015166575A1 WO2015166575A1 PCT/JP2014/062108 JP2014062108W WO2015166575A1 WO 2015166575 A1 WO2015166575 A1 WO 2015166575A1 JP 2014062108 W JP2014062108 W JP 2014062108W WO 2015166575 A1 WO2015166575 A1 WO 2015166575A1
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- 230000005855 radiation Effects 0.000 title claims abstract description 439
- 238000003325 tomography Methods 0.000 title claims abstract description 168
- 238000001514 detection method Methods 0.000 claims abstract description 166
- 238000003384 imaging method Methods 0.000 claims abstract description 146
- 238000004364 calculation method Methods 0.000 claims abstract description 56
- 230000001133 acceleration Effects 0.000 claims description 11
- 230000001678 irradiating effect Effects 0.000 claims description 9
- 230000002452 interceptive effect Effects 0.000 abstract description 2
- 230000007246 mechanism Effects 0.000 description 69
- 238000000034 method Methods 0.000 description 19
- 238000010586 diagram Methods 0.000 description 5
- 230000005540 biological transmission Effects 0.000 description 4
- 230000008859 change Effects 0.000 description 3
- 230000000694 effects Effects 0.000 description 3
- 230000008569 process Effects 0.000 description 3
- 230000014509 gene expression Effects 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 230000003187 abdominal effect Effects 0.000 description 1
- 230000004397 blinking Effects 0.000 description 1
- 238000005192 partition Methods 0.000 description 1
- 230000004044 response Effects 0.000 description 1
- 230000001360 synchronised effect Effects 0.000 description 1
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/02—Arrangements for diagnosis sequentially in different planes; Stereoscopic radiation diagnosis
- A61B6/025—Tomosynthesis
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/40—Arrangements for generating radiation specially adapted for radiation diagnosis
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/44—Constructional features of apparatus for radiation diagnosis
- A61B6/4429—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units
- A61B6/4464—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units the source unit or the detector unit being mounted to ceiling
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/46—Arrangements for interfacing with the operator or the patient
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/54—Control of apparatus or devices for radiation diagnosis
- A61B6/547—Control of apparatus or devices for radiation diagnosis involving tracking of position of the device or parts of the device
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/44—Constructional features of apparatus for radiation diagnosis
- A61B6/4429—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units
- A61B6/4452—Constructional features of apparatus for radiation diagnosis related to the mounting of source units and detector units the source unit and the detector unit being able to move relative to each other
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
- A61B6/52—Devices using data or image processing specially adapted for radiation diagnosis
- A61B6/5205—Devices using data or image processing specially adapted for radiation diagnosis involving processing of raw data to produce diagnostic data
Definitions
- the present invention relates to a radiation tomography apparatus including a radiation source and a radiation detector, and more particularly to a technique for automatically calculating a range of the position of the radiation detector that enables imaging of a radiation tomographic image.
- a radiation tomography apparatus using an imaging technique called tomosynthesis is used as an apparatus for acquiring a tomographic image of a cut surface of a subject using radiation (for example, Patent Documents 1 and 2).
- each of a radiation source and a radiation detector is arranged to face each other with a subject interposed therebetween.
- the radiation source captures a series of radiation images while moving relative to the radiation detector.
- a radiological tomographic image of the subject is reconstructed by digital processing and displayed on a display unit such as a monitor.
- a flat panel detector FPD: Flat Panel Detector
- the configuration of a radiation tomography apparatus according to a conventional example will be described with reference to FIG.
- the conventional radiation tomography apparatus 100 includes a support column 101, a radiation source 103, an FPD 105, and a moving mechanism 107.
- the radiation source 103 is attached to a column 101 having a base on the ceiling of the examination room so as to be movable up and down.
- the radiation source 103 moves relative to the subject M while moving in the y direction, that is, in the body axis direction of the subject M, from the position indicated by the solid line to the position indicated by the broken line, as indicated by an arrow in FIG. Radiation is intermittently emitted from the focal point 103a.
- the FPD 105 detects the radiation irradiated from the focal point 103a and passed through the subject M, and outputs it as a radiation detection signal. Based on the radiation detection signal output from the FPD 105, a radiation image of the subject M is generated.
- the moving mechanism 107 controls the movement of the radiation source 103 in the y direction, and controls the radiation source 103 so that the central axis 103b of the radiation beam emitted from the focal point 103a always passes through the center point P of the detection surface of the FPD 105. Tilt to the y direction.
- the radiation source 103 sequentially changes the radiation irradiation angle, so that the radiation source 103 can always irradiate the center point P with radiation.
- F is the height from the floor surface W to the center point P of the detection surface of the FPD 105.
- the moving mechanism 107 may move the radiation source 103 and the FPD 105 synchronously. That is, the moving mechanism 107 moves the radiation source 103 and the FPD 105 in the y direction in opposite directions so that the central axis 103b of the X-ray beam passes through the tomographic center Q that is the region of interest. That is, the radiation source 103 and the FPD 105 are synchronously moved in directions opposite to each other with the subject M interposed therebetween while maintaining the arrangement facing each other. In this case, a radiation image is generated for the reference tomographic plane Ma including the tomographic center Q and parallel to the detection surface of the FPD 107.
- the magnification of the acquired radiation tomographic image is affected by the distance (imaging distance) between the focal point 103a and the detection surface of the FPD 105, and the tomographic thickness of the radiation tomographic image is the radiation source 103 during intermittent irradiation of radiation. Affected by the swing angle (irradiation swing angle).
- the imaging distance G shown in FIG.
- the irradiation swing angle ⁇ In order to reduce the tomographic thickness of the radiation tomographic image, it is preferable to increase the irradiation swing angle ⁇ .
- JP 2002-263093 A Japanese Patent Application Laid-Open No. 2012-10078
- the conventional example having such a configuration has the following problems.
- the problem is concerned.
- the movable range of the radiation source 103 moving in the vertical direction is limited to at least the range from the ceiling surface to the floor surface. Further, since the radiation source 103 is a heavy load, the support column 101 that supports the radiation source 103 and the moving mechanism 107 that moves the radiation source 103 need to have a strong configuration. Accordingly, the movable range of the radiation source 103 is further narrowed due to such mechanical constraints.
- the moving region of the radiation source 103 may extend outside the movable range of the radiation source 103 in tomography.
- the radiation source 103 needs to move from the position indicated by the solid line to the position indicated by the broken line in order to acquire the radiation tomographic image.
- the range in which the radiation source 103 moves that is, the movement region of the radiation source 103 is a range indicated by a symbol J from the position indicated by the solid line to the position indicated by the broken line.
- the position indicated by the broken line is lower than the floor surface, the radiation source 103 cannot move to the position indicated by the broken line. Such a situation also occurs when the irradiation swing angle ⁇ is increased or when the shooting distance G is increased.
- the radiation source 103 and the FPD 105 are synchronously moved in opposite directions as shown in FIG. 20B, the radiation source 103 is moved depending on the distance (tomographic plane height) between the reference tomographic plane Ma and the detection plane of the FPD 105.
- the area J may deviate from the movable range. That is, even when the irradiation swing angle ⁇ and the imaging distance G are the same, the moving region J of the radiation source 103 becomes narrow when the tomographic plane height H is large (FIG. 22A).
- the radiation source 103 may interfere with the ceiling surface, the floor surface, or the like. Further, even after the radiation source 103 starts moving, even if the operator notices that the moving area J of the radiation source 103 is outside the movable range of the radiation source 103 and stops the radiation tomography, The time for the radiation tomography that was canceled will be lost. That is, since it takes time to perform the radiation tomography again, the time required for capturing the radiation tomographic image becomes longer. Further, since the subject M is irradiated with radiation again, there is a concern that the exposure amount of the subject M increases.
- the present invention has been made in view of such circumstances, and an object of the present invention is to provide a radiation tomography apparatus that calculates in advance the range of the position of an FPD capable of capturing a radiation tomographic image.
- the present invention has the following configuration. That is, the radiation tomography apparatus according to the present invention includes a radiation source that irradiates a subject with radiation, radiation detection means that detects radiation transmitted through the subject, and the radiation source is moved in the body axis direction of the subject.
- Radiation source moving means Radiation source moving means, radiation irradiation control means for controlling the radiation source to repeat radiation irradiation while the radiation source moving means moves the radiation source, and for each radiation irradiation by the radiation source,
- An image generating means for generating a radiation image using a detection signal output from the radiation detecting means;
- a tomographic image acquiring means for acquiring a radiation tomographic image by reconstructing a plurality of radiation images generated by the image generating means;
- An imaging distance that is a distance from the focal point of the radiation source to the detection surface of the radiation detection unit, and the radiation irradiation control unit causes the radiation source to repeat radiation irradiation.
- the radiation tomographic image is obtained without the radiation source deviating from the movable range of the radiation source based on a parameter group consisting of an irradiation swing angle that is a swing angle of the radiation source and a movable range of the radiation source.
- the image capturing apparatus includes an image capturing range calculation unit that calculates an image capturing range of the radiation detection unit, which is a range of the position of the radiation detection unit that can be acquired.
- the imageable range calculation unit calculates the imageable range of the radiation detection unit based on a parameter group including an imaging distance, an irradiation swing angle, and a movable range of the radiation source.
- the imaging distance and the irradiation swing angle are parameters that are arbitrarily determined by the operator in advance in accordance with the tomographic thickness and magnification ratio of the radiation tomographic image.
- the movable range of the radiation source is a parameter determined in advance according to the standard of the radiation tomography apparatus. Therefore, the operator can calculate in advance the imaging range of the radiation detection means before performing radiation tomography based on the imaging distance, the irradiation swing angle, and the movable range of the radiation source.
- the radiographable range of the radiation detection means is a range of positions of the radiation detection means where the radiation source can acquire a radiation tomographic image without deviating from the movable range of the radiation source. Therefore, by referring to the pre-calculated range of the radiation detection means that can be imaged, the radiation detection means can be reliably moved within the imageable range and radiation tomography can be started. Therefore, there are situations where the radiation source moves out of the movable range of the radiation source and interferes with the floor, etc., or the radiation tomography is canceled after predicting the interference of the radiation source after the start of the radiation tomography. It can be avoided reliably. As a result, it is possible to reduce the time required for radiation tomography by preventing time and effort for re-imaging, and it is therefore possible to efficiently shoot high-quality radiation tomographic images.
- the present invention may have the following configuration. That is, the radiation tomography apparatus according to the present invention includes a radiation source that irradiates a subject with radiation, radiation detection means that detects radiation transmitted through the subject, and the radiation source is moved in the body axis direction of the subject.
- Radiation source moving means Radiation source moving means, radiation irradiation control means for controlling the radiation source to repeat radiation irradiation while the radiation source moving means moves the radiation source, and for each radiation irradiation by the radiation source,
- An image generating means for generating a radiation image using a detection signal output from the radiation detecting means;
- a tomographic image acquiring means for acquiring a radiation tomographic image by reconstructing a plurality of radiation images generated by the image generating means; With the radiation detection means facing the radiation source across the subject, the radiation source moving means is moved in a direction opposite to the direction in which the radiation source is moved.
- Detector moving means an imaging distance that is a distance from a focal point of the radiation source to a detection surface of the radiation detection means, and a swing of the radiation source while the radiation irradiation control means causes the radiation source to repeat radiation irradiation.
- the radiation source is based on a parameter group consisting of an irradiation swing angle that is an angle, a movable range of the radiation source, and a tomographic plane height that is a distance from a detection surface of the radiation detection means to a tomographic center.
- a radiographable range calculation means for calculating a radiographable range of the radiation detection means which is a range of positions of the radiation detection means capable of acquiring the radiation tomographic image without deviating from the movable range of It is a feature.
- the imageable range calculation means can image the radiation detection means based on a parameter group consisting of the imaging distance, the irradiation swing angle, the movable range of the radiation source, and the height of the tomographic plane. Calculate the range.
- the imaging distance, the irradiation swing angle, and the tomographic plane height are parameters that are arbitrarily determined by the operator in advance in accordance with the tomographic thickness and magnification of the radiation tomographic image.
- the movable range of the radiation source is a parameter determined in advance according to the standard of the radiation tomography apparatus. Therefore, the operator can calculate in advance the imaging range of the radiation detection means before performing the radiation tomography based on the imaging distance, the irradiation swing angle, the movable range of the radiation source, and the tomographic plane height.
- the radiographable range of the radiation detection means is a range of positions of the radiation detection means where the radiation source can acquire a radiation tomographic image without deviating from the movable range of the radiation source. Therefore, by referring to the pre-calculated range of the radiation detection means that can be imaged, the radiation detection means can be reliably moved within the imageable range and radiation tomography can be started. Therefore, there are situations where the radiation source moves out of the movable range of the radiation source and interferes with the floor, etc., or the radiation tomography is canceled after predicting the interference of the radiation source after the start of the radiation tomography. It can be avoided reliably. As a result, it is possible to reduce the time required for radiation tomography by preventing labor and time for re-imaging, so that a high-quality radiation tomographic image can be efficiently captured.
- the radiation moving means moves the radiation detecting means in a direction opposite to the direction in which the radiation source moving means moves the radiation source in a state of facing the radiation source with the subject interposed therebetween. Therefore, a radiation image for reconstructing a radiation tomographic image can be generated in a region away from the radiation detection means. That is, a radiographic image can be suitably generated even when the region of interest is on the ventral side of the subject. Therefore, it is possible to acquire a radiation tomographic image over a wider range including the ventral side of the subject.
- the parameter group is an acceleration distance from which the radiation source is accelerated, and an acceleration distance from an imaging preparation position of the radiation source to an irradiation start position, and the radiation source is decelerated. It is preferable to further include a deceleration distance from the irradiation end position of the radiation source to the imaging end position, which is a moving distance.
- the parameter group further includes an acceleration distance and a deceleration distance.
- the acceleration distance is a distance that the radiation source moves while accelerating from the imaging preparation position to the irradiation start position.
- the deceleration distance is the distance that the radiation source moves while decelerating from the irradiation end position to the imaging end position.
- Both the acceleration distance and the deceleration distance are parameters that can be determined in advance before performing X-ray tomography according to the moving speed of the radiation source. Therefore, the operator can preliminarily calculate the imageable range of the radiation detection means before performing radiation tomography by using a predetermined parameter group.
- the radiation source moves while accelerating the acceleration distance from the imaging preparation position to the irradiation start position. Then, it moves while decelerating from the irradiation end position to the imaging end position. That is, the radiation source moves while repeatedly irradiating radiation from the irradiation start position to the irradiation end position while maintaining the moving speed.
- the radiation source can intermittently emit radiation while moving at a constant speed, and a series of radiation images can be generated.
- the moving speed of the radiation source is constant, the timing for intermittently irradiating radiation to generate a series of radiation images can be calculated more easily. Therefore, it is possible to perform control for capturing a suitable radiation tomographic image more accurately and easily.
- the radiation tomography apparatus further includes an input unit for inputting the parameter group, and the imaging range calculation means is input to the input unit every time the parameter group is input to the input unit.
- the radiation tomography apparatus includes an input unit for inputting a parameter group including an imaging distance and an irradiation swing angle.
- the imaging range calculation unit calculates the imaging range of the radiation detection unit based on the newly input parameter group. Therefore, even if it is necessary to change any of the parameter groups, the imageable range can be quickly recalculated by inputting the parameter groups to the input unit. Therefore, it is possible to more reliably calculate the imageable range of the radiation detection means before the radiation tomography, and to perform the radiation tomography appropriately and efficiently.
- the radiation tomography apparatus further includes detector position calculation means for calculating the position of the radiation detection means.
- the radiation tomography apparatus includes detector position calculating means for calculating the position of the radiation detecting means. Therefore, it is possible to determine whether or not the radiation detection means is located within the imaging possible range by referring to the position of the radiation detection means calculated by the detector position calculation means. Therefore, there are situations where the radiation source moves out of the movable range of the radiation source and interferes with the floor, etc., or the radiation tomography is canceled after predicting the interference of the radiation source after the start of the radiation tomography. It can be avoided more reliably.
- the radiation tomography apparatus may further include a warning unit that issues a warning when the position of the radiation detection unit calculated by the detector position calculation unit is outside the imaging range of the radiation detection unit. preferable.
- the warning means is used when the position of the radiation detection means is outside the imaging range of the radiation detection means. Make a warning.
- the operator can quickly and surely confirm that the position of the radiation detection means is outside the imaging range of the radiation detection means by sensing the warning. Therefore, the operator can move the radiation detection means more quickly and reliably within the imaging possible range, so that a high-quality radiation tomographic image can be captured more efficiently.
- the radiation tomography apparatus can image the radiation detection means when the position of the radiation detection means calculated by the detector position calculation means is outside the imageable range of the radiation detection means. It is preferable to provide detector movement control means for controlling the detector movement means so as to move to a range.
- the detector movement control means allows the position of the radiation detection means to be outside the imaging range of the radiation detection means.
- the detector moving means is controlled.
- the detector moving means moves the radiation detecting means to the imageable range in accordance with the control of the detector movement control means. For this reason, even if the operator does not notice that the position of the radiation detection means is outside the imaging range of the radiation detection means, the radiation detection means is surely positioned within the imaging range. Therefore, since the radiation detection means can be moved more reliably within the imageable range, a high-quality radiation tomographic image can be imaged more efficiently.
- the imageable range calculation unit calculates the imageable range of the radiation detection unit based on a parameter group including an imaging distance, an irradiation swing angle, and a movable range of the radiation source.
- the imaging distance and the irradiation swing angle are parameters that are arbitrarily determined by the operator in advance in accordance with the tomographic thickness and magnification ratio of the radiation tomographic image.
- the movable range of the radiation source is a parameter determined in advance according to the standard of the radiation tomography apparatus. Therefore, the operator can calculate in advance the imaging range of the radiation detection means before performing radiation tomography based on the imaging distance, the irradiation swing angle, and the movable range of the radiation source.
- the radiographable range of the radiation detection means is a range of positions of the radiation detection means where the radiation source can acquire a radiation tomographic image without deviating from the movable range of the radiation source. Therefore, X-ray tomography can be started by reliably moving the radiation detection means within the imageable range by referring to the imageable range of the radiation detection means calculated in advance. Therefore, it is possible to reliably avoid the occurrence of a situation in which the radiation source moves out of the movable range of the radiation source and interferes with the floor surface or a situation in which the radiation tomography is stopped in anticipation of the interference of the radiation source. As a result, it is possible to prevent time and labor for re-imaging, so that radiation tomography can be performed suitably and efficiently.
- FIG. 1 is a schematic diagram illustrating a configuration of a radiation tomography apparatus according to Embodiment 1.
- FIG. 1 is a functional block diagram illustrating a configuration of a radiation tomography apparatus according to Embodiment 1.
- FIG. FIG. 6 is a schematic diagram illustrating a method for calculating an FPD imageable range in the first embodiment.
- (A) is a figure explaining the calculation method of the height of a X-ray focus based on the height of a center point, an imaging distance, and an irradiation swing angle
- (b) is a movable range of an X-ray tube, an imaging distance, and It is a figure explaining the method of calculating the imaging
- FIG. 3 is a flowchart for explaining an operation process in the radiation tomography apparatus according to Embodiment 1; It is the schematic which shows the radiation tomography apparatus in step S1 which concerns on Example 1.
- FIG. It is the schematic which shows the radiation tomography apparatus in step S2 which concerns on Example 1.
- FIG. It is the schematic which shows the radiation tomography apparatus in step S3 which concerns on Example 1.
- FIG. (A) is a figure explaining the movement to the x direction of a X-ray tube support part
- (b) is a figure explaining the movement to the y direction of the X-ray tube, and the inclination with respect to ay direction.
- FIG. FIG.
- Example 3 is a schematic diagram illustrating a configuration of a radiation tomography apparatus according to a second embodiment.
- Example 2 it is a figure explaining the calculation method of the height of a X-ray focus based on the height of a region of interest, an imaging distance, an irradiation swing angle, and a tomographic plane height.
- Example 2 it is a figure explaining the method to calculate the imaging
- FIG. It is the schematic which shows the radiation tomography apparatus in step S2 which concerns on Example 2.
- FIG. 6 is a schematic diagram illustrating a configuration of a radiation tomography apparatus according to a third embodiment.
- (A) is a figure which shows the imaging preparation position and imaging
- (b) is a graph explaining the change of the moving speed of an X-ray tube.
- it is a figure explaining the calculation method of the height of a X-ray focus based on the height of a center point, an imaging distance, and an irradiation swing angle.
- it is a figure explaining the calculation method of the height of a X-ray focus based on the height of a region of interest, an imaging distance, an irradiation swing angle, and a tomographic plane height.
- (A) is a figure which shows the structure which fixes the position of FPD, and performs a radiation tomography
- (b) The structure which performs a radiation tomography by synchronizing and moving FPD to a X-ray tube and a mutually opposite direction is shown. It is a figure. It is the schematic explaining the problem of the radiation tomography apparatus which concerns on a prior art example. It is the schematic explaining the problem of the radiation tomography apparatus which concerns on a prior art example. (A) shows the case where the fault plane height is high, and (b) shows the case where the fault plane height is low.
- Embodiment 1 of the present invention will be described below with reference to the drawings.
- it demonstrates using an X-ray as an example of a radiation.
- the radiation tomography apparatus 1 includes an X-ray tube 3 and an FPD 5 that are disposed to face each other with a subject M interposed therebetween.
- the X-ray tube 3 is supported by an X-ray tube support 7 and irradiates the subject M with X-rays 3b from the X-ray focal point 3a.
- the base of the X-ray tube support portion 7 is provided on the ceiling of the examination room, and moves horizontally in the x direction along rails 9 laid on the ceiling.
- the X-ray tube 3 is provided with a collimator 11 that limits the X-ray 3b irradiated from the X-ray focal point 3a to a cone shape that is a pyramid.
- the FPD 5 is attached to a support column 13 standing vertically on the floor of the examination room so as to be movable up and down.
- the FPD 5 detects the X-ray 3b irradiated to and transmitted through the subject M from the X-ray focal point 3a, converts it into an electrical signal, and outputs it as an X-ray detection signal.
- the X-ray tube 3 corresponds to the radiation source in the present invention
- the FPD 5 corresponds to the radiation detection means in the present invention.
- the X-ray tube 3 is provided with an X-ray tube moving mechanism 15, an X-ray irradiation control unit 17, and an X-ray tube rotating mechanism 19.
- the X-ray tube 3 is configured to move along the X-ray tube support portion 7 in the y direction, that is, in the body axis direction of the subject M in accordance with the operation of the X-ray tube moving mechanism 15. In the embodiment, since the subject M has a standing posture, the X-ray tube 3 moves in the vertical direction.
- the X-ray irradiation control unit 17 is configured to output a high voltage to the X-ray tube 3. And based on the high voltage output and control signal which X-ray irradiation control part 17 gave, the X-ray dose which X-ray tube 3 irradiates, and the timing which irradiates X-rays are controlled.
- the X-ray tube 3 is configured to be rotatable around an axis in the z direction by an X-ray tube rotating mechanism 19. Accordingly, the X-ray tube rotation mechanism 19 can be operated to change the angle at which the X-ray tube 3 irradiates X-rays without changing its spatial position.
- the X-ray tube moving mechanism 15 corresponds to the radiation source moving means in the present invention
- the X-ray irradiation control unit 17 corresponds to the radiation irradiation control means in the present invention.
- a support moving mechanism 20 is attached to the X-ray tube support 7.
- the support part moving mechanism 20 horizontally moves the X-ray tube support part 7 along the rail 9 in the x direction. Since the X-ray tube 3 is supported by the X-ray tube support portion 7, the X-ray tube 3 moves horizontally in the x direction as the X-ray tube support portion 7 moves.
- the brake 21 and the FPD moving mechanism 23 are attached to the FPD 5.
- the brake 21 suppresses the movement of the FPD 5 in the y direction.
- the FPD moving mechanism 23 controls on / off of the brake 21. Further, the FPD 5 is configured to move in the y direction along the support column 13 in accordance with the operation of the FPD moving mechanism 23.
- the FPD 5 has a configuration that enables manual movement in addition to movement by the FPD moving mechanism 23. That is, the operator can manually move the FPD 5 in the y direction along the support column 13 after releasing the brake 21.
- the FPD moving mechanism 23 corresponds to the detector moving means in the present invention.
- the image generation unit 25 is provided in the subsequent stage of the FPD 5, and the tomographic image reconstruction unit 27 is provided in the subsequent stage of the image generation unit 25.
- the image generation unit 25 forms an X-ray image of the subject M based on the X-ray detection signal output from the FPD 5.
- the tomographic image reconstruction unit 27 acquires an X-ray tomographic image by reconstructing a plurality of X-ray images generated by the image generation unit 25.
- a monitor 29 is connected to the tomographic image reconstruction unit 27, and the monitor 29 displays the X-ray tomographic image reconstructed by the tomographic image reconstruction unit 27.
- the image generation unit 25 corresponds to the image generation unit in the present invention
- the tomographic image reconstruction unit 27 corresponds to the tomographic image acquisition unit in the present invention.
- the X-ray image corresponds to the radiation image in the present invention.
- the main control unit 31 includes an X-ray tube moving mechanism 15, an X-ray irradiation control unit 17, an X-ray tube rotating mechanism 19, a support unit moving mechanism 20, an FPD moving mechanism 23, an image generating unit 25, a tomographic image reconstruction unit 27, and a monitor. 29 is controlled overall.
- the input unit 33 is a keyboard input type panel or a touch input type panel, and the main control unit 31 performs overall control according to an instruction input to the input unit 33 by the operator.
- the main control unit 31 corresponds to detector movement control means in the present invention.
- the imaging range calculation unit 35 calculates the imaging range of the FPD 5 based on parameters input by the operator to the input unit 37.
- the imageable range of the FPD 5 is a range of positions of the FPD 5 in which an X-ray tomographic image can be imaged without the movement region of the X-ray tube 3 being outside the movable range of the X-ray tube 3. A method for calculating the shootable range of the FPD 5 and a parameter for calculating the shootable range of the FPD 5 will be described later.
- the storage unit 37 stores the X-ray tomographic image acquired by the tomographic image reconstruction unit 27, information on the imageable range of the FPD 5 calculated by the imaging range calculation unit 35, and the like.
- the shooting range calculation unit 35 corresponds to the shooting range calculation means in the present invention.
- the main control unit 31 controls the X-ray tube moving mechanism 15 and the X-ray tube rotating mechanism 19 so that the X-ray tube 3 always faces the FPD 5 with X-rays. It is configured to irradiate 3b. That is, as shown in FIG. 1, the X-ray tube moving mechanism 15 moves the X-ray tube 3 in the y direction from the position indicated by the solid line to the position indicated by the broken line, and the X-ray tube rotating mechanism 19 is the central axis of the X-ray 3b.
- the X-ray tube 3 is inclined with respect to the y direction so that 3c always passes through the center point P of the detection surface of the FPD 5.
- the X-ray tube 3 Since the X-ray tube 3 sequentially changes the angle at which the X-ray 3b is irradiated in conjunction with the movement in the y direction, the X-ray tube 3 can always irradiate the FPD 5 with the X-ray 3b.
- the X-ray tube 3 is provided with an X-ray tube detector 39, and the FPD 5 is provided with an FPD detector 41.
- the X-ray tube detection unit 39 detects the amount of movement of the X-ray tube 3 in the y direction and the amount of movement of the X-ray tube support unit 7 in the x direction as needed. Then, the X-ray tube detection unit 39 calculates position information of the X-ray tube 3 as needed based on the detected amounts of movement.
- the FPD detection unit 41 detects the amount of movement of the FPD 5 in the y direction as needed. Then, the FPD detection unit 41 calculates position information of the FPD 5 as needed based on the detected movement amount.
- the X-ray tube detection unit 39 and the FPD detection unit 41 are both configured by a potentiometer, but an encoder or the like may be used instead of the potentiometer.
- the position information of the X-ray tube 3 calculated by the X-ray tube detection unit 39 and the position information of the FPD 5 calculated by the FPD detection unit 41 are stored in the storage unit 37 as needed.
- the radiation tomography apparatus 1 further includes a warning sound transmitter 43.
- the position information of the FPD 5 calculated by the FPD detection unit 41 and the information of the shootable range of the FPD 5 calculated by the shooting range calculation unit 35 are transmitted to the warning sound transmission unit 43 through the main control unit 31 as needed.
- the warning sound transmitting unit 43 is configured to transmit a warning sound when the current position of the FPD 5 is out of the FPD 5 imageable range. Examples of warning sounds include buzzer sounds and voices.
- the position of the X-ray focal point 3a at the time when the X-ray tube 3 first irradiates X-rays in X-ray tomography is hereinafter referred to as “irradiation start position”.
- the position of the X-ray focal point 3a at the time when the X-ray tube 3 finally irradiates the X-ray is hereinafter referred to as an “irradiation end position”, and is indicated by a symbol B.
- the straight line AB is a moving region of the X-ray tube 3, that is, a range in which the X-ray focal point 3a moves during X-ray tomography.
- the movement region of the X-ray tube 3 will be described with reference J.
- the photographing distance G corresponds to a so-called focus-image receiving surface distance (SID: Source Image Distance).
- SID Source Image Distance
- the swing angle of the X-ray tube 3 from the irradiation start position A to the irradiation end position B (hereinafter referred to as “irradiation swing angle”), that is, the size of the APB is defined as ⁇ . It is assumed that the position of the center point P of the detection surface of the FPD 5 is fixed when X-ray irradiation is performed, and the height from the floor surface W to the center point P is F.
- the intersection of the normal line of the detection surface of the FPD 5 passing through the center point P and the straight line AB is defined as C.
- the X-ray tube 3 moves so that the angles of ⁇ APC and ⁇ BPC are equal. Accordingly, the sizes of ⁇ APC and ⁇ BPC are both ( ⁇ / 2).
- the straight line AB is parallel to the y direction, the straight line PC and the straight line AB are orthogonal to each other. Since the length of the straight line PC is equal to the length G of the photographing distance, the length DAC of the straight line AC and the length D BC of the straight line BC are calculated using the following formula (1).
- the movable range of the X-ray tube 3 is determined in advance due to mechanical limitations of the radiation tomography apparatus 1. For that reason from the floor surface to the X-ray focal point 3a of the height and S, the minimum value S min of the maximum value S max and height S of the height S are predetermined, information S max and S min is stored Stored in the unit 37.
- the movable range of the X-ray tube 3 determined by S max and S min will be described below with reference sign SP.
- the movement area J of the X-ray tube 3 is always included within the movable range SP. That will not exceed the maximum value S max height Sa height S of the irradiation start position A, since no less than the minimum value S min height Sb height S of the irradiation end position B, S max The expressions ⁇ Sa and S min ⁇ Sb hold.
- the range of the height F from the floor surface W to the center point P of the detection surface of the FPD 5 is calculated using the following equation (4).
- the shooting range calculation unit 35 uses the shooting distance G, the irradiation swing angle ⁇ , the maximum value S max of the height S, and the minimum value S min of the height S, to the center point P of the FPD 5 from the floor surface W.
- the range of the height F up to can be calculated.
- the maximum value of the height F calculated by the equation (4) above, that is, S max ⁇ G ⁇ tan ( ⁇ / 2) is hereinafter referred to as F max .
- the minimum value of the height F calculated by the equation (4) above, that is, S min + G tan ( ⁇ / 2) is hereinafter referred to as F min .
- the imageable range of the FPD 5 can be calculated using F max and F min .
- F max Smax
- F min the position of the center point P of the detection surface of the FPD 5
- P1 the position of the center point P of the detection surface of the FPD 5
- P2 the position of the center point P of the detection surface of the FPD 5
- the movement region J of the X-ray tube 3 is included within the movable range SP of the X-ray tube 3.
- the X-ray tube 3 does not move outside the movable range SP of the X-ray tube 3 when performing X-ray tomography. That is, the imageable range of the FPD 5 is a range where the FPD 5 is located when the center point P of the FPD 5 is located on the straight line P 1 P 2 .
- the maximum value of the height from the floor surface W to the upper end of the FPD 5 is (F max + R).
- the minimum height from the floor surface W to the lower end of the FPD 5 is (F min -R).
- the length of R is a value determined in advance according to the size of the FPD 5. Accordingly, the imageable range of the FPD 5 is determined using F max , F min , and R. Note that the shootable range of the FPD 5 that is determined using F max , F min , and R will be described below with the reference symbol FP.
- the imaging distance G and the irradiation swing angle ⁇ are parameters that are arbitrarily determined by the operator in advance before the start of X-ray tomography according to the tomographic thickness and magnification of the X-ray tomographic image.
- S max and S min are parameters determined in advance according to the standard of the radiation tomography apparatus 1. Therefore, the operator calculates in advance the imaging range FP of the FPD 5 before starting the movement of the X-ray tube 3 and performs X-ray tomography in a state where the FPD 5 is surely positioned within the imaging range FP. be able to. As a result, since the X-ray tube 3 can be prevented from moving outside the movable range SP during X-ray tomography, X-ray tomographic imaging can be suitably performed.
- FIG. 4 is a flowchart for explaining an operation process in the radiation tomography apparatus according to the first embodiment. As shown in FIG. 5, it is assumed that the subject M is in a standing posture in the radiation tomography apparatus 1, and the X-ray tube 3 and the FPD 5 are in positions indicated by solid lines in FIG.
- Step S1 (calculation of photographing range)
- the operator calculates the shootable range of the FPD 5. That is, the operator operates the input unit 33 to input parameters for the shooting distance G and the irradiation swing angle ⁇ . Each input parameter is transmitted to the imaging range calculation unit 35.
- the storage unit 37 stores parameters of a maximum value S max of the height S from the floor surface W to the X-ray focal point 3a and a minimum value S min of the height S. The parameters of the maximum value S max and the minimum value S min are transmitted from the storage unit 37 to the shooting range calculation unit 35.
- the imaging range calculation unit 35 sets the maximum value F max and the minimum value for the height F from the floor surface to the center point P of the detection surface of the FPD 5.
- F min is calculated.
- R be the length from the center point P of the FPD 5 to the upper end of the FPD 5 and from the center point P of the FPD 5 to the lower end of the FPD 5.
- the imageable range FP of the FPD 5 is determined as a range in which the upper limit is (F max + R) and the lower limit is (F min ⁇ R) using F max , F min , and R.
- the center point P of the detection surface of the FPD 5 is located on the straight line P 1 P 2 .
- the X-ray tube 3 is out of the movable range SP during X-ray tomography under the conditions of the imaging distance G and the irradiation swing angle ⁇ . Do not move to.
- the imageable range FP of the FPD 5 that can suitably image X-ray tomographic images under the conditions of the imaging distance G and the irradiation swing angle ⁇ is calculated.
- the operator may input only the parameter of the irradiation swing angle ⁇ without inputting the parameter of the shooting distance G to the input unit 33.
- information on the current position of the X-ray tube 3 calculated by the X-ray tube detection unit 39 and information on the current position of the FPD 5 calculated by the FPD detection unit 41 are transmitted from the storage unit 37 to the imaging range calculation unit 35. Is done.
- the imaging range calculation unit 35 calculates the current distance from the X-ray focal point 3a to the detection surface of the FPD 5 as the imaging distance G based on each of the transmitted position information. Then, the shooting range calculation unit 35 calculates the shooting range FP of the FPD 5 using the calculated shooting distance G.
- Step S2 movement of FPD position
- the photographing range calculation unit 35 calculates the photographing possible range FP of the FPD 5
- the position of the FPD 5 is moved. Therefore, the operator first moves to the FPD 5 side and operates the brake 21 to turn it off.
- the brake 21 is turned off, the FPD 5 can be moved up and down in the y direction along the column 13. Then, as shown in FIG. 6, the operator manually moves the FPD 5 from the position indicated by the broken line to the position indicated by the solid line according to the position of the region of interest of the subject M.
- the position information of the FPD 5 calculated by the FPD detection unit 41 and the information of the movable range FR of the FPD 5 calculated by the imaging range calculation unit 35 are transmitted to the warning sound transmission unit 43 as needed.
- the warning sound transmitter 43 transmits a warning sound. The operator can confirm that the position of the FPD 5 is out of the shootable range FP by the warning sound transmitted by the warning sound transmitter 43.
- the operator can quickly take measures for appropriately performing X-ray tomography in response to the transmission of the warning sound.
- Examples of countermeasures include a method of moving the FPD 5 into the range of the shootable range FP, or newly inputting parameters of the shooting distance G and the irradiation swing angle ⁇ to the input unit 33.
- Step S3 preparation for X-ray irradiation
- the operator operates the input unit 33 to input an instruction for preparing for X-ray irradiation.
- a control signal is output from the main control unit 31 to the X-ray tube moving mechanism 15, the X-ray tube rotating mechanism 19, and the support unit moving mechanism 20.
- the support portion moving mechanism 20 moves the X-ray tube support portion 7 in the x direction from the position indicated by the broken line to the position indicated by the solid line as shown in FIG. 7A based on the given control signal. Since the X-ray tube 3 is supported by the X-ray tube support portion 7, the X-ray tube 3 moves in the x direction according to the X-ray tube support portion 7.
- the position of the X-ray tube support portion 7 indicated by a solid line is a position where the distance from the X-ray focal point 3a to the detection surface of the FPD 5, that is, the length of the imaging distance is G.
- the X-ray tube moving mechanism 15 moves the X-ray tube 3 with a broken line as shown in FIG. 7B based on the given control signal. Move in the y direction from the indicated position to the position indicated by the solid line.
- the position of the X-ray focal point 3a of the X-ray tube 3 indicated by the solid line in FIG. 7B is hereinafter referred to as “imaging preparation position”.
- imaging preparation position it is assumed that the imaging preparation position and the irradiation start position A coincide. That is, if the height F from the floor surface W to the center point P, the shooting distance G, and the irradiation swing angle ⁇ are used, the height from the floor surface W to the shooting preparation position is (F + Gtan ( ⁇ / 2)).
- the X-ray tube rotating mechanism 19 tilts the X-ray tube 3 with respect to the y direction based on the given control signal.
- the inclination angle of the X-ray tube 3 is controlled so that the central axis 3c of the X-rays irradiated from the X-ray focal point 3a passes through the center point P of the detection surface of the FPD 5.
- the preparation for X-ray irradiation is completed by moving the X-ray tube 3 so that the position of the X-ray focal point 3a becomes the imaging preparation position.
- Step S4 Generation of X-ray image
- the operator operates the input unit 33 to input an instruction to start X-ray irradiation.
- a control signal is output from the main control unit 31 to the X-ray tube moving mechanism 15, the X-ray irradiation control unit 17, and the X-ray tube rotation mechanism 19.
- the X-ray tube moving mechanism 15 moves the X-ray tube 3 straight in the y direction along the X-ray tube support portion 7 based on the given control signal.
- the X-ray focal point 3a is controlled to move straight from an irradiation start position A (imaging preparation position) indicated by a solid line in FIG. 8 to an irradiation end position B indicated by a broken line.
- the X-ray irradiation control unit 17 irradiates the cone-shaped X-ray 3b from the X-ray focal point 3a that moves straight in the y direction based on the signal output from the main control unit 31.
- the irradiated X-ray 3 b passes through the subject M and is detected by the FPD 5.
- the FPD 5 that has detected the X-ray 3 b outputs an X-ray detection signal, and the output X-ray detection signal is transmitted to the image generation unit 25.
- the image generation unit 25 generates an X-ray image based on the transmitted X-ray detection signal.
- the X-ray tube rotating mechanism 19 causes the X-ray tube rotation mechanism 19 so that the central axis 3c of the X-ray 3b always passes through the center point P of the detection surface of the FPD 5. 3 is controlled to be inclined with respect to the y direction. That is, the X-ray tube rotating mechanism 19 rotates the X-ray tube 3 around the axis in the z direction based on the signal output from the main control unit 31, and controls the inclination angle of the X-ray tube 3 with respect to the y direction.
- the collimator 11 controls the shape of the X-ray 3b so that the X-ray 3b irradiated from the X-ray focal point 3a is incident on the entire surface of the FPD 5. Since the angle of irradiating the X-ray 3b is sequentially changed in conjunction with the movement of the X-ray tube 3 in the y direction, the X-ray tube 3 can always irradiate the FPD 5 with the X-ray 3b.
- the X-ray 3b is irradiated intermittently from the X-ray focal point 3a.
- the number of times of irradiation with X-rays 3b is several tens of times or more, for example, 74 times. Since an X-ray image is generated each time the X-ray 3b is irradiated, each time the X-ray tube 3 is moved in the y direction, a series of X images taken from different directions with respect to the region of interest of the subject M. A line image is generated.
- the generated X-ray image data is sent from the image generation unit 25 to the tomographic image reconstruction unit 27.
- the X-ray tube 3 ends the X-ray irradiation at the irradiation end position B and stops moving in the y direction.
- Step S5 (Acquisition of X-ray tomographic image)
- the tomographic image reconstruction unit 27 reconstructs image information relating to the series of X-ray images.
- X-ray tomographic image data of the subject M at a desired cutting position can be acquired by reconstructing image information related to the X-ray image.
- the monitor 29 displays the X-ray tomographic image data acquired by the tomographic image reconstruction unit 27.
- the filter back projection method (FBP method) is used as a method for reconstructing image information, but a shift addition method or the like may be used instead.
- the radiation tomography apparatus 1 includes an imaging range calculation unit 35.
- the imaging range calculation unit 35 calculates the imaging range of the FPD 5 based on the imaging distance G, the irradiation swing angle ⁇ , and the movable range SP of the X-ray tube 3.
- the imaging distance G and the irradiation swing angle ⁇ are parameters that are arbitrarily determined by the operator in advance each time an X-ray tomographic image is taken according to the tomographic thickness and magnification of the X-ray tomographic image.
- the movable range SP of the X-ray tube 3 is a parameter predetermined for the radiation tomography apparatus 1. Therefore, the operator can calculate in advance the imageable range FP of the FPD 5 before starting the movement of the X-ray tube 3 by inputting the parameters of the imaging distance G and the irradiation swing angle ⁇ to the input unit 33.
- the imageable range FP of the FPD 5 is a range of positions of the FPD 5 in which an X-ray tomographic image can be imaged without the movement region of the X-ray tube 3 extending outside the movable range of the X-ray tube 3. Accordingly, the movement region J of the X-ray tube 3 is started by starting the movement of the X-ray tube 3 with the FPD 5 being moved within the range of the imageable range FPD with reference to the imageable range FP calculated in advance. An X-ray tomographic image can be taken without going outside the movable range SP of the X-ray tube 3.
- the radiation tomography apparatus cannot calculate the FPD imageable range. Therefore, depending on parameters such as the height of the center point of the FPD, the shooting distance, or the irradiation swing angle, the FPD may be located outside the FPD shooting range. If radiation tomography is executed in this case, the X-ray tube may move out of the movable range and interfere with the ceiling surface or floor surface.
- an ultrasonic sensor may be provided as an example in order to prevent the X-ray tube from interfering with a ceiling surface or a floor surface.
- the ultrasonic sensor detects the possibility that the X-ray tube may interfere with the ceiling surface or floor surface based on the position and moving speed of the X-ray tube, and stops the movement of the X-ray tube. Can be avoided.
- the ultrasonic sensor predicts the possibility that the X-ray tube interferes with the floor surface or the like after the X-ray tube starts moving.
- the process of starting the movement of the X-ray tube corresponds to step S3 in the first embodiment. Therefore, X-ray tomographic imaging cannot be stopped until after the X-ray tube starts moving. As a result, the time and effort spent on the operation performed before the X-ray tube starts moving is lost. Further, when the X-ray tomography is stopped after the X-ray tube starts the X-ray irradiation, it is necessary to irradiate the subject with radiation again, so that the exposure amount of the subject increases.
- the radiation tomography apparatus 1 calculates the imageable range FP of the FPD 5 in the step S1 in which the imaging distance and the irradiation swing angle are input to the input unit 33.
- step S2 the operator moves from the place where the input unit 33 is located to the FPD 5 side, and moves the position of the FPD 5. Since the shootable range FP of the FPD 5 has already been calculated at this time, the operator can reliably move the FPD 5 into the shootable range FP with reference to the shootable range FP.
- the operator again moves from the FPD 5 side to the place where the input unit 33 is located and inputs an instruction to prepare for X-ray tomography (step S3), and further operates the input unit 33 to acquire an X-ray tomographic image. (Steps S4 and S5).
- the FPD 5 is surely located within the photographing possible range at the time of step S3. Therefore, in X-ray tomography, it is possible to avoid the occurrence of a situation in which the X-ray tube 3 interferes with the floor surface or the like, or a situation in which the X-ray tomography is stopped halfway by detecting the possibility that the X-ray tube 3 interferes. .
- the operator When the X-ray tomography is stopped after step S3, the operator re-enters the parameters of the imaging distance and the irradiation swing angle, and further moves the location of the input unit 33 and the side of the FPD 5 in order to move the position of the FPD 5. It is necessary to make a round trip.
- the operator In the radiation tomography apparatus according to the first embodiment, it is possible to avoid a situation in which imaging is stopped after step S3. Therefore, the operator can take an X-ray tomographic image without spending time and effort for re-input or reciprocation. it can.
- the exposure dose of the subject M in X-ray tomography can be suppressed.
- the radiation tomography apparatus 1 includes a warning sound transmitting unit 43, and transmits a warning sound when the position of the FPD 5 is out of the imageable range FP.
- the warning sound is composed of a buzzer sound or a voice. Therefore, the operator can easily confirm that the position of the FPD 5 is out of the shootable range FP by listening to the warning sound. Therefore, the operator can surely move the FPD 5 within the photographing possible range.
- the main control unit 31 performs overall control of the X-ray tube moving mechanism 15, the X-ray tube rotating mechanism 19, and the FPD moving mechanism 23, thereby performing X-ray tomography.
- the X-ray tube 3 and the FPD 5 are moved synchronously. That is, as shown in FIG. 9, the X-ray tube moving mechanism 15 moves the X-ray tube 3 straight from the solid line position to the broken line position in the y direction, and the FPD moving mechanism 23 moves the FPD 5 from the solid line position to the broken line position. Move straight in the y direction. That is, the X-ray tube 3 and the FPD 5 are synchronously moved in opposite directions with the subject M interposed therebetween while maintaining the arrangement facing each other.
- the X-ray tube rotation mechanism 19 tilts the X-ray tube 3 with respect to the y direction so that the central axis 3c of the X-ray 3b always passes through the tomographic center Q.
- the FPD moving mechanism 23 moves the center axis 3c in the FPD 5y direction so that the center axis 3c always passes through the center point P of the detection surface of the FPD 5. Since the X-ray tube 3 sequentially changes the angle at which the X-ray 3b is irradiated in conjunction with the movement in the y direction, the X-ray tube 3 can always irradiate the FPD 5 intermittently with the X-ray 3b.
- the image generation unit 25 generates a large number of X-ray images of the reference tomographic plane Ma that is the tomographic plane including the tomographic center Q and parallel to the detection plane of the FPD 5 based on the X-ray detection signal transmitted from the FPD 5.
- the tomographic image reconstruction unit 27 can acquire an X-ray tomographic image at a desired cut surface by reconstructing an X-ray image of the reference tomographic plane Ma.
- a partition 45 is installed between the subject M and the FPD 5.
- the screen 45 stably maintains the position of the subject M taking a standing posture and prevents interference between the FPD 5 moving in the y direction and the subject M.
- Example 2 As shown in FIG. 10, in Example 2, the central axis 3c of the X-ray 3b irradiated from the X-ray focal point 3a always passes through the tomographic center Q. Therefore, in Example 2, the irradiation swing angle of the X-ray tube 3 in X-ray tomography corresponds to ⁇ AQB.
- the magnitude of the irradiation swing angle is assumed to be ⁇ .
- the distance from the fault center Q to the detection surface of the FPD 5 (hereinafter referred to as “fault plane height”) is H, and the height from the floor W to the fault center Q is T.
- the position of the center point P of the detection surface of the FPD 5 when the X-ray focal point 3a is at the irradiation start position A is hereinafter referred to as “detection start position” and is denoted by reference symbol Pa.
- the position of the center point P in the case where the X-ray focal point 3a is located at the irradiation end position B is hereinafter referred to as “detection end position” and is denoted by reference symbol Pb. That is, the straight line PaPb is a moving region of the FPD 5, that is, a range in which the center point 5 of the detection surface of the FPD 5 moves during X-ray tomography.
- the height from the floor surface W to the detection start position Pa is Fa.
- the height from the floor surface W to the detection end position Pb is defined as Fb.
- the intersection of the perpendicular line L drawn from the fault center Q to the detection surface of the FPD 5 and the straight line AB is C
- the intersection point of the perpendicular L and the straight line PaPb is E.
- the X-ray tube 3 moves so that the angles of ⁇ AQC and ⁇ BQC are equal. Accordingly, the sizes of ⁇ APC and ⁇ BPC are both ( ⁇ / 2). Further, since the straight line AB is parallel to the y direction, the perpendicular L and the straight line AB are orthogonal.
- the length of the straight line CE is equal to the photographing distance G and the length of the straight line EQ is equal to the tomographic plane height H, the length of the straight line CQ is (GH). Therefore, the length D BC of linear AC length D AC and the line BC is calculated using the formula represented by the following (5).
- the height Sa from the floor surface W to the irradiation start position A and the height Sb from the floor surface to the irradiation end position B are expressed by the following (6) using the height T from the floor surface W to the fault center Q. And it calculates with the formula shown by (7).
- the movement area J of the X-ray tube 3 is always included within the movable range SP. Accordingly, the range of the height T from the floor surface to the region of interest Q is calculated using the following equation (11). S max ⁇ (GH) tan ( ⁇ / 2) ⁇ T ⁇ S min + (GH) tan ( ⁇ / 2) (8)
- the imaging range calculation unit 35 uses the imaging distance G, the irradiation swing angle ⁇ , the tomographic plane height H, the maximum value S max of the height S, and the minimum value S min of the height S to obtain the height T. Can be calculated. Note that the maximum value of the height T calculated by the equation (8) above, that is, S max ⁇ (GH) tan ( ⁇ / 2) is defined as T max . Then, the minimum value of the height F calculated by the equation (8) above, that is, S min + (GH) tan ( ⁇ / 2) is defined as T min .
- the range of the position of the tomographic center Q such that the movement area J of the X-ray tube 3 is within the range of the movable range SP of the X-ray tube 3 can be calculated based on T max and T min .
- the height T of the fault center Q is T min .
- Indicating the position of the tomographic center Q in this case by the reference numeral Q 2. That is, when the tomographic center Q is located on the straight line Q 1 Q 2 , the movement region J of the X-ray tube 3 is included within the movable range SP of the X-ray tube 3.
- the operator moves the FPD 5 in accordance with the region of interest of the subject M in step S2.
- the position of the tomographic center Q is calculated based on the position of the center point P on the detection surface of the FPD 5. That is, the position of the fault center Q is determined so that the height F of the center point P after the movement of the FPD 5 is equal to the height T from the floor surface W to the fault center Q. Therefore, the shootable range FP of the FPD 5 can be calculated by using T max and T min .
- the tomographic center Q is located on the straight line Q 1 Q 2 . Therefore, when X-ray tomography is performed, the movement region J of the X-ray tube 3 is within the movable range SP of the X-ray tube 3. That is, the imageable range of the FPD 5 is a range where the FPD 5 is located when the center point P of the FPD 5 is located on the straight line P 3 P 4 .
- the upper limit of the imageable range FP is a position where the height F is (T max + R).
- the lower limit of the shootable range FP is a position where the height F is (T min ⁇ R).
- the length of R is a value determined in advance according to the size of the FPD 5. Therefore, the imageable range FP of the FPD 5 can be determined in advance using T max , T min , and R.
- the imaging range calculation unit 35 uses the imaging distance G, the irradiation swing angle ⁇ , the tomographic plane height H, the maximum value S max of the height S, and the minimum value S min of the height S to enable the imaging range of the FPD 5.
- FP can be calculated.
- the tomographic plane height H is the distance between the tomographic center Q corresponding to the region of interest of the subject M and the detection surface of the FPD 5. Therefore, the tomographic plane height H is a parameter arbitrarily determined by the operator before performing X-ray tomography according to the distance between the detection surface of the FPD 5 and the screen 45, the physique of the subject M, and the like.
- the operator calculates in advance the imaging range FP of the FPD 5 before starting the movement of the X-ray tube 3 and performs X-ray tomography in a state where the FPD 5 is surely positioned within the imaging range FP. be able to.
- the height Fa from the floor surface W to the detection start position Pa and the height Fb from the floor surface W to the detection end position Pb can also be calculated using the tomographic plane height H and the swing angle ⁇ .
- the length of the straight line EQ is equal to the fault plane height H.
- the sizes of ⁇ EQPa and ⁇ EQPb are both ( ⁇ / 2). Therefore, the length D EPa of the straight line EPa and the length D EPb of the straight line EPb are calculated using the following equation (9).
- Step S1 (calculation of photographing range)
- the operator calculates the shootable range of the FPD 5. That is, the operator operates the input unit 33 to input parameters of the imaging distance G, the irradiation swing angle ⁇ , and the tomographic plane height H. The input parameters are transmitted to the imaging range calculation unit 35. Also, the parameters of the maximum value S max of the height S from the floor surface W to the X-ray focal point 3 a and the minimum value S min of the height S are transmitted from the storage unit 37 to the imaging range calculation unit 35.
- the imaging range calculation unit 35 Based on the transmitted parameters, that is, G, ⁇ , H, S max , and S min , the imaging range calculation unit 35 has a maximum value T max and a minimum value T min for the height T from the floor surface W to the tomographic center Q. Is calculated. At this time, the upper limit value (T max + R) and the lower limit value (T min ⁇ R) of the shootable range FP of the FPD 5 are calculated using T max , T min , and the constant R. As described above, the imageable range FP of the FPD 5 capable of suitably capturing an X-ray tomographic image is calculated under the conditions of the imaging distance G, the irradiation swing angle ⁇ , and the tomographic plane height H.
- Step S2 movement of FPD position
- the photographing range calculation unit 35 calculates the photographing possible range FP of the FPD 5
- the position of the FPD 5 is moved. Therefore, the operator first moves to the FPD 5 side and operates the brake 21 to turn it off. Then, as shown in FIG. 13, the operator manually moves the FPD 5 from the position indicated by the broken line to the position indicated by the solid line according to the region of interest of the subject M.
- the warning sound transmitter 43 transmits a warning sound.
- the operator can confirm that the position of the FPD 5 is out of the shootable range FP by the warning sound transmitted by the warning sound transmitter 43. After confirming that the position of the FPD 5 is within the shootable range FP, the operator operates the brake 21 to turn it on to fix the position of the FPD 5.
- the position of the fault center Q is determined based on the position of the center point P of the detection surface of the FPD 5. That is, the FPD detection unit 41 calculates the position information of the FPD 5 as needed, and calculates the height F from the floor surface W to the center point P based on the position information of the FPD 5. Then, the FPD detection unit 41 calculates the position where the height from the floor surface W is F and the distance from the center point P in the x direction is H as the tomographic center Q. That is, the height T from the bottom surface W to the fault center Q is equal to the height F from the floor surface W to the center point P.
- the storage unit 37 stores the calculated position information of the tomographic center Q.
- Step S3 preparation for X-ray tomography
- the operator operates the input unit 33 to input an instruction to prepare for X-ray tomography.
- a control signal is output from the main control unit 31 to the X-ray tube moving mechanism 15, the X-ray tube rotating mechanism 19, the support moving mechanism 20, and the FPD moving mechanism 23.
- the support part moving mechanism 20 moves the X-ray tube support part 7 in the x direction based on the given control signal.
- the X-ray tube moving mechanism 15 moves the X-ray tube 3 in the y direction based on the given control signal.
- the X-ray tube rotating mechanism 19 tilts the X-ray tube 3 with respect to the y direction based on the given control signal. As a result, as shown in FIG. 14, the X-ray tube 3 moves from the position indicated by the broken line to the imaging preparation position indicated by the solid line.
- the imaging preparation position of the X-ray tube 3 coincides with the irradiation start position A of the X-ray tube 3. That is, at the imaging preparation position of the X-ray tube 3, the height from the floor surface W to the X-ray focal point 3a is equal to Sa. Therefore, as described above, using the height T from the floor surface W to the tomographic center Q, the imaging distance G, and the irradiation swing angle ⁇ , the height from the floor surface W to the X-ray focal point 3a is (T + (GH). ) ⁇ Tan ( ⁇ / 2)).
- the height T from the floor surface W to the fault center Q is equal to the height F from the floor surface W to the center point P. Accordingly, the height from the floor surface W to the X-ray focal point 3a at the imaging preparation position of the X-ray tube 3 is (F + (GH) ⁇ tan ( ⁇ / 2)). Further, since the length of the imaging distance is G, the length of the perpendicular line dropped from the X-ray focal point 3a to the detection surface of the FPD 5 at the imaging preparation position of the X-ray tube 3 is G. Thus, the imaging preparation position of the X-ray tube 3 is determined based on the height F from the floor surface W to the center point P, the imaging distance G, the irradiation swing angle ⁇ , and the tomographic plane height H.
- the FPD moving mechanism 23 moves the FPD 5 to the detection preparation position based on the given control signal.
- the detection preparation position of the FPD 5 coincides with the detection start position Pa of the FPD 5. Therefore, at the detection preparation position of the FPD 5, the height from the floor surface W to the center point P is equal to the height Fa from the floor surface W to the detection start position Pa. As described above, the height Fa from the floor surface W to the detection start position Pa is T-Htan ( ⁇ / 2).
- the height T from the floor surface W to the fault center Q is equal to the height F of the center point P of the FPD 5 moved in step S2. Therefore, at the detection preparation position of the FPD 5, the height from the floor surface W to the center point P is F-Htan ( ⁇ / 2). Thus, the detection preparation position of the FPD 5 is determined based on the height F of the center point P of the FPD 5 moved in step S2, the irradiation swing angle ⁇ , and the tomographic plane height H.
- Step S4 Generation of X-ray image
- the X-ray tube 3 is controlled by the X-ray tube moving mechanism 15 so as to move straight from an irradiation start position indicated by a solid line in FIG. 15 to an irradiation end position indicated by a broken line.
- the FPD 5 is controlled by the FPD moving mechanism 23 so as to move straight from the detection start position indicated by the solid line to the detection end position indicated by the broken line.
- the X-ray irradiation control unit 17 irradiates the cone-shaped X-ray 3b from the X-ray focal point 3a that moves straight in the y direction based on the signal output from the main control unit 31.
- the irradiated X-ray 3 b passes through the subject M and is detected by the FPD 5.
- the FPD 5 that has detected the X-ray 3 b outputs an X-ray detection signal, and the output X-ray detection signal is transmitted to the image generation unit 25.
- the image generation unit 25 generates an X-ray image based on the transmitted X-ray detection signal.
- the generated X-ray image data is sent from the image generation unit 25 to the tomographic image reconstruction unit 27.
- the X-ray tube rotating mechanism 19 moves the X-ray tube 3 in the y direction so that the central axis 3c of the X-ray 3b always passes the region of interest Q. It is controlled to incline with respect to it. That is, the X-ray tube rotating mechanism 19 rotates the X-ray tube 3 around the axis in the z direction based on the signal output from the main control unit 31, and controls the inclination angle of the X-ray tube 3 with respect to the y direction.
- Step S5 (Acquisition of X-ray tomographic image)
- the tomographic image reconstruction unit 27 reconstructs image information relating to the series of X-ray images.
- X-ray tomographic image data of the subject M at a desired cutting position can be acquired by reconstructing image information related to the X-ray image.
- the monitor 29 displays the X-ray tomographic image data acquired by the tomographic image reconstruction unit 27.
- the imaging range calculation unit 35 calculates the imaging possible range of the FPD 5 before performing X-ray tomography.
- the imageable range of the FPD 5 is calculated based on the imaging distance G, the irradiation swing angle ⁇ , the tomographic plane height H, and the movable range SP of the X-ray tube 3.
- the imaging distance G, the irradiation swing angle ⁇ , and the tomographic plane height H are parameters arbitrarily determined in advance by the operator every time an X-ray tomographic image is taken.
- the movable range SP of the X-ray tube 3 is a parameter predetermined for the radiation tomography apparatus 1. Therefore, the operator can calculate in advance the imageable range of the FPD 5 based on these parameters before the start of the movement of the X-ray tube.
- the imageable range of the FPD 5 is a range of positions of the FPD 5 in which an X-ray tomographic image can be imaged without the movement region of the X-ray tube 3 being outside the movable range of the X-ray tube 3. Accordingly, in X-ray tomography, it is possible to reliably avoid the occurrence of a situation where the X-ray tube 3 interferes with the floor surface or a situation where the X-ray tube 3 predicts the interference and stops the imaging. Can be carried out in a suitable and efficient manner.
- an X-ray tomographic image can be acquired over a wider range. That is, when X-ray tomography is performed with the position of the FPD 5 fixed, a region where all the X-ray images for reconstructing the X-ray tomographic image can be formed is a region U indicated by diagonal lines in FIG. . In this case, the region U is particularly narrow on the ventral side of the subject M. That is, when the abdominal side of the subject M is used as a region of interest, acquisition of an X-ray tomographic image may be difficult.
- the region U is a region indicated by diagonal lines in FIG. Therefore, even when the region of interest is on the ventral side of the subject M, an X-ray tomographic image can be suitably acquired. Therefore, in the radiation tomography apparatus 1A according to the second embodiment, X-ray tomography can be suitably and efficiently performed on a wider region of interest as compared with the case where the position of the FPD 5 is fixed.
- Embodiment 3 of the present invention will be described with reference to the drawings.
- the configuration and operation steps of the radiation tomography apparatus according to the third embodiment are the same as those of the radiation tomography apparatus 1 according to the first embodiment or the radiation tomography apparatus 1A according to the second embodiment, and thus detailed description will be given. Is omitted.
- Example 1 and Example 2 the imaging preparation position of the X-ray tube 3 coincides with the irradiation start position A of the X-ray tube 3.
- Example 3 as shown in FIG. 17A, the imaging preparation position of the X-ray tube 3 indicated by the symbol Af and the irradiation start position A of the X-ray tube 3 are different.
- the third embodiment differs from the first and second embodiments in whether or not the imaging preparation position of the X-ray tube 3 matches the irradiation start position.
- the distance from the imaging preparation position Af to the irradiation start position A is hereinafter referred to as an acceleration distance R1
- the distance from the imaging end position Bf to the irradiation end position B is hereinafter referred to as a deceleration distance R2.
- the X-ray tube 3 moved to the imaging preparation position Af in step S3 starts moving in the y direction along the X-ray tube support portion 7 after the start of step S4 (FIG. 17B). , T0).
- the X-ray tube 3 starts irradiating the subject M with X-rays 3b at the irradiation start position A (t1).
- the X-ray tube 3 moves from the irradiation start position A to the irradiation end position B at a constant speed while irradiating the X-ray 3b intermittently.
- the X-ray tube 3 ends the irradiation of the X-ray 3b at the irradiation end position B (t2).
- the X-ray tube 3 moves from the irradiation end position B to the imaging end position Bf while decelerating, and stops moving at the imaging end position Bf (t3).
- the moving speed Vs of the X-ray tube 3 at this time is shown in FIG.
- the moving speed Vs is accelerated from the start time t0 of step S4 to time t1, and reaches a predetermined speed V1 at time t1.
- the moving speed Vs maintains the predetermined speed V1 until time t2 when the X-ray tube 3 reaches the irradiation end position B.
- the moving speed Vs is decelerated from time t2 to time t3.
- the moving speed Vs becomes 0, and the X-ray tube 3 stops moving.
- the height Saf and the height Sbf are the height F from the floor surface W to the center point P of the detection surface of the FPD 5.
- the shooting distance G, and the irradiation swing angle ⁇ are both ( ⁇ / 2).
- the movement region J of the X-ray tube 3 is always included in the range of the movable range SP of the X-ray tube 3. Therefore, the maximum value S max of the height S from the floor surface W to the X-ray focal point 3a is always greater than or equal to the height Saf, and the minimum value S min of the height S is always less than or equal to the height Sbf, so S max ⁇ Saf And S min ⁇ Sbf. Therefore, the range of the height F from the floor surface to the center point P of the detection surface of the FPD 5 is calculated using the following equation (14). S max ⁇ G tan ( ⁇ / 2) ⁇ R 1 ⁇ F ⁇ S min + G tan ( ⁇ / 2) + R 2 (14)
- the maximum value of the height F calculated by the equation (14) above that is, S max ⁇ G ⁇ tan ( ⁇ / 2) ⁇ R1 is defined as F max .
- the minimum value of the height F that is, S min + Gtan ( ⁇ / 2) + R2 is defined as F min .
- R be the length from the center point P to the upper end of the FPD 5 and from the center point P to the lower end of the FPD 5.
- the imageable range FP of the FPD 5 is defined as a range in which the upper limit is (F max + R) and the lower limit is (F min -R) using F max , F min , and R, as in the first embodiment.
- the shooting range calculation unit 35 can calculate the shooting range FP of the FPD 5 using parameters such as the shooting distance G.
- the imaging distance G and the irradiation swing angle ⁇ are parameters that the operator arbitrarily determines in advance for each X-ray tomography.
- S max and S min are parameters determined in advance according to the standard of the X-ray tube 3 and the size of the examination room.
- the length of R is a parameter determined in advance according to the size of the FPD 5.
- the acceleration distance R1 and the deceleration distance R2 are determined according to the weight of the X-ray tube 3 or the like and the moving speed V1 of the X-ray tube 3 during X-ray irradiation. That is, the acceleration distance R1 and the deceleration distance R2 are parameters that are predetermined according to the standard of the radiation tomography apparatus 1. Therefore, the operator can calculate in advance the imaging range FP of the FPD 5 before performing X-ray tomography in Example 3 as shown in FIG. 18 by using a predetermined parameter group.
- Example 3 when the FPD 5 is configured to move opposite to the X-ray tube 3 when performing X-ray tomography, the height Saf and the height Sbf are the parts of interest from the floor surface W.
- the calculation is performed as follows.
- the maximum value of the height T calculated by the equation (17) above that is, S max ⁇ (GH) tan ( ⁇ / 2) ⁇ R1 is defined as T max .
- the minimum value of the height T calculated by the equation (18), that is, S min + (GH) tan ( ⁇ / 2) + R2 is defined as T min .
- R be the length from the center point P of the FPD 5 to the upper end of the FPD 5 and from the center point P of the FPD 5 to the lower end of the FPD 5.
- the imageable range FP of the FPD 5 is defined as a range in which the upper limit is (T max + R) and the lower limit is (T min -R) using T max , T min , and R, as in the second embodiment. .
- the shooting range calculation unit 35 can calculate the shooting range FP of the FPD 5 using parameters such as the shooting distance G. All parameters used for calculating the imaging range FP are parameters that can be determined in advance before performing X-ray tomography. Therefore, the operator can calculate in advance the imaging range FP of the FPD 5 before performing X-ray tomography in Example 3 as shown in FIG. 19 by using a predetermined parameter group.
- the X-ray tomography is started in a state where the FPD 5 is surely positioned within the imaging range FP. can do.
- the X-ray tube 3 is prevented from moving outside the movable range SP during X-ray tomography, and X-ray tomographic imaging is preferably performed. be able to.
- a distance R1 is provided.
- a deceleration distance R2 for reducing the moving speed Vs of the X-ray tube 3 is provided between the irradiation end position B of the X-ray tube 3 and the imaging end position Bf of the X-ray tube 3.
- the moving speed Vs is accelerated while the X-ray tube 3 moves from the imaging preparation position Af to the irradiation start position A in step S4, and reaches a constant speed V1 at the irradiation start position A.
- the X-ray tube 3 moves from the irradiation start position A to the irradiation end position B while irradiating the X-ray 3b intermittently while maintaining the speed V1.
- the moving speed Vs is decelerated while moving from the irradiation end position B to the photographing end position Bf, and the moving speed Vs becomes zero at the photographing end position Bf.
- the X-ray tube 3 irradiates X-rays intermittently while moving at a constant speed, and generates a series of X-ray images. be able to.
- the moving speed Vs of the X-ray tube 3 is constant, the timing for intermittently irradiating X-rays to generate a series of X-ray images can be calculated more easily. For this reason, it is possible to perform control for capturing a suitable X-ray tomographic image more accurately and easily.
- the present invention is not limited to the above embodiment, and can be modified as follows.
- the X-ray tube rotating mechanism 19 tilts the X-ray tube 3 with respect to the y direction so that the central axis 3c of the X-ray 3b always passes through the center point P of the detection surface of the FPD 5.
- the present invention is not limited to this. That is, the point through which the central axis 3c of the X-ray 3b always passes (the center point of the X-ray irradiation field) may be an arbitrary point on the detection surface of the FPD 5.
- the imageable range FP of the FPD 5 can be calculated by appropriately replacing the center point P of the detection surface of the FPD 5 with a position that becomes the center point of the X-ray irradiation field on the detection surface of the FPD 5. .
- the size of the FPD 5 and the size of the X-ray field may be different. In such a case, the position of the X-ray irradiation field may deviate from the center of the detection surface of the FPD 5.
- the imaging possible range FP of the FPD 5 can be accurately calculated even when the position of the X-ray irradiation field is deviated from the center of the detection surface of the FPD 5.
- the shootable range FP of the FPD 5 is calculated by setting the length from the center point P of the FPD 5 to the upper end of the FPD 5 and from the center point P to the lower end of the FPD 5 as R.
- the present invention is not limited to this. Absent.
- the imageable range FP of the FPD 5 may be calculated by replacing the length R with the length from the center point P (or the center point of the X-ray irradiation field) to the upper end (or lower end) of the X-ray irradiation field. .
- the FPD moving mechanism 23 may be controlled so that the FPD 5 moves into the shootable range FP. That is, when the FPD 5 is outside the shootable range FP, the main control unit 31 transmits a signal to the FPD moving mechanism 23. The FPD moving mechanism 23 switches the brake 21 to the off state based on the control signal, and moves the FPD 5 in the y direction.
- the FPD detection unit 41 calculates the position of the FPD 5 and transmits a signal to the FPD moving mechanism via the main control unit 31.
- the FPD moving mechanism 23 switches the brake 21 to the on state based on the control signal, and stops the movement of the FPD 5.
- the FPD detection unit 41 calculates the position of the FPD 5 and transmits a signal to the FPD moving mechanism via the main control unit 31 when the position of the FPD 5 is displaced outside the shootable range FP.
- the FPD moving mechanism 23 switches the brake 21 to the on state based on the control signal, and stops the movement of the FPD 5.
- the warning sound transmitter 43 transmits a warning sound.
- the FPD 5 is within the shootable range FP.
- the means for notifying that the user is outside is not limited to a warning sound. That is, it is good also as a structure which notifies by blinking and lighting an LED lamp and other indicators.
- a warning message may be displayed on a monitor or the like to notify that the FPD 5 is out of the shootable range FP.
- the base of the X-ray tube support portion 7 is provided on the ceiling of the examination room, and moves horizontally in the x direction along the rail 9 laid on the ceiling. I can't.
- the X-ray tube support portion 7 may have a base portion on the floor surface W and horizontally move in the x direction along the rail 9 laid on the floor surface W.
- the irradiation start position A is located above the irradiation end position B, and the X-ray tube 3 is configured to move in the y direction from above to below in X-ray tomography. Not limited to this. That is, the irradiation start position A may be set below the irradiation end position B, and the X-ray tube 3 may be configured to intermittently perform X-ray irradiation while moving from below to above.
- the X-ray tomography is performed on the subject M in the standing posture, but the configuration according to each embodiment is applied to the subject in the supine posture. Can be applied.
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Abstract
Description
すなわち、従来の放射線断層撮影装置において、床面Wから中心点Pまでの高さF、撮影距離G、または照射振り角度θなどのパラメータによっては、放射線断層画像の撮影を効率的に行えなくなるという問題が懸念される。
すなわち、本発明に係る放射線断層撮影装置は、被検体に放射線を照射する放射線源と、被検体を透過した放射線を検出する放射線検出手段と、前記放射線源を被検体の体軸方向に移動させる放射線源移動手段と、前記放射線源移動手段が前記放射線源を移動させている間に、前記放射線源に放射線照射を繰り返させる制御を行う放射線照射制御手段と、前記放射線源による放射線照射毎に前記放射線検出手段が出力する検出信号を用いて放射線画像を生成する画像生成手段と、前記画像生成手段が生成した複数の放射線画像を再構成させて放射線断層画像を取得する断層画像取得手段と、前記放射線源の焦点から前記放射線検出手段の検出面までの距離である撮影距離、前記放射線照射制御手段が前記放射線源に放射線照射を繰り返させる間における前記放射線源の振り角度である照射振り角度、および前記放射線源の移動可能範囲からなるパラメータ群に基づいて、前記放射線源が前記放射線源の移動可能範囲を逸脱することなく前記放射線断層画像を取得できる前記放射線検出手段の位置の範囲である、前記放射線検出手段の撮影可能範囲を算出する撮影可能範囲算出手段とを備えていることを特徴とするものである。
すなわち、本発明に係る放射線断層撮影装置は、被検体に放射線を照射する放射線源と、被検体を透過した放射線を検出する放射線検出手段と、前記放射線源を被検体の体軸方向に移動させる放射線源移動手段と、前記放射線源移動手段が前記放射線源を移動させている間に、前記放射線源に放射線照射を繰り返させる制御を行う放射線照射制御手段と、前記放射線源による放射線照射毎に前記放射線検出手段が出力する検出信号を用いて放射線画像を生成する画像生成手段と、前記画像生成手段が生成した複数の放射線画像を再構成させて放射線断層画像を取得する断層画像取得手段と、前記放射線検出手段を、前記被検体を挟んで前記放射線源と対向させた状態で前記放射線源移動手段が前記放射線源を移動させる方向と逆向きに移動させる検出器移動手段と、前記放射線源の焦点から前記放射線検出手段の検出面までの距離である撮影距離、前記放射線照射制御手段が前記放射線源に放射線照射を繰り返させる間における前記放射線源の振り角度である照射振り角度、前記放射線源の移動可能範囲、および前記放射線検出手段の検出面から断層中心までの距離である断層面高さからなるパラメータ群に基づいて、前記放射線源が前記放射線源の移動可能範囲を逸脱することなく前記放射線断層画像を取得できる前記放射線検出手段の位置の範囲である、前記放射線検出手段の撮影可能範囲を算出する撮影可能範囲算出手段とを備えていることを特徴とするものである。
実施例1に係る放射線断層撮影装置1は図1に示すように、被検体Mを挟んで対向配置されたX線管3とFPD5とを備えている。X線管3はX線管支持部7によって支持されており、被検体Mに対してX線焦点3aからX線3bを照射する。X線管支持部7は基部が検査室の天井に設けられており、天井に敷設されたレール9に沿ってx方向へ水平移動する。X線管3には、X線焦点3aから照射されるX線3bを角錐となっているコーン状に制限するコリメータ11が設けられている。
ここで実施例1において撮影範囲算出部35がFPD5の撮影可能範囲を算出する方法について説明する。
DAC=DBC=Gtan(θ/2)…(1)
Sa=F+DAC=F+Gtan(θ/2)…(2)
Sb=F-DBC=F-Gtan(θ/2)…(3)
Smax-Gtan(θ/2)≧F≧Smin+Gtan(θ/2)…(4)
次に、実施例1に係る放射線断層撮影装置1の動作について説明する。図4は実施例1に係る放射線断層撮影装置における動作の工程を説明するフローチャートである。なお、図5に示すように、放射線断層撮影装置1において被検体Mは立位姿勢をとっており、X線管3およびFPD5は図5において実線で示される位置にあるものとする。
まず操作者はFPD5の撮影可能範囲を算出する。すなわち操作者は入力部33を操作して撮影距離Gおよび照射振り角度θのパラメータを入力する。入力された各パラメータは撮影範囲算出部35へ送信される。また、記憶部37には床面WからX線焦点3aまでの高さSの最大値Smax、および高さSの最小値Sminのパラメータが記憶されている。そして最大値Smax、および最小値Sminのパラメータが記憶部37から撮影範囲算出部35へ送信される。
撮影範囲算出部35がFPD5の撮影可能範囲FPを算出した後、FPD5の位置の移動を行う。そこでまず操作者はFPD5の側へ移動し、ブレーキ21を操作してオフの状態にする。ブレーキ21がオフの状態となることによって、FPD5は支柱13に沿ってy方向へ上下移動可能となる。そして図6に示すように、操作者は被検体Mの関心部位の位置に応じて、FPD5を破線で示す位置から実線で示す位置へ手動で移動させる。
FPD5の位置の移動が終了した後、次にX線照射の準備を行う。すなわち操作者は入力部33を操作して、X線照射の準備を行う指示を入力する。入力部33に入力される指示に従って、主制御部31からX線管移動機構15、X線管回転機構19、および支持部移動機構20へ制御信号が出力される。
X線照射の準備が完了した後、次にX線画像の生成を行う。すなわち操作者は入力部33を操作して、X線の照射を開始する指示を入力する。入力部33に入力される指示に従って、主制御部31からX線管移動機構15、X線照射制御部17、およびX線管回転機構19へ制御信号が出力される。X線管移動機構15は与えられた制御信号に基づいて、X線管3をX線管支持部7に沿ってy方向に直進移動させる。具体的には、図8において実線で示される照射開始位置A(撮影準備位置)から、破線で示される照射終了位置BへX線焦点3aが直進移動するように制御される。
一連のX線画像が生成されると、断層画像再構成部27は一連のX線画像に係る画像情報を再構成する。X線画像に係る画像情報の再構成によって、所望の裁断位置における被検体MのX線断層画像データを取得できる。モニタ29は断層画像再構成部27において取得されたX線断層画像データを表示させる。なお実施例1において、画像情報の再構成を行う方法としてフィルタバックプロジェクション法(FBP法)を用いるが、これに代えてシフト加算法などを用いてもよい。
実施例1に係る放射線断層撮影装置1は撮影範囲算出部35を備えている。撮影範囲算出部35は撮影距離G、照射振り角度θ、およびX線管3の移動可能範囲SPに基づいてFPD5の撮影可能範囲を算出する。
実施例2に係る放射線断層撮影装置1Aでは、主制御部31がX線管移動機構15、X線管回転機構19、およびFPD移動機構23を統括制御することにより、X線断層撮影の際にX線管3とFPD5を同期的に移動させる。すなわち図9に示すように、X線管移動機構15はX線管3を実線の位置から破線の位置へy方向に直進移動させるとともに、FPD移動機構23はFPD5を実線の位置から破線の位置へy方向に直進移動させる。つまり、X線管3およびFPD5は互いに対向する配置を保ったまま、被検体Mを挟んで互いに逆向きに同期移動する。
ここで実施例2において撮影範囲算出部35がFPD5の撮影可能範囲を算出する方法について説明する。
DAC=DBC=(G-H)tan(θ/2)…(5)
Sa=T+DAC=T+(G-H)tan(θ/2)…(6)
Sb=T-DBC=T-(G-H)tan(θ/2)…(7)
Smax-(G-H)tan(θ/2)≧T≧Smin+(G-H)tan(θ/2)…(8)
DEPa=DEPb=Htan(θ/2)…(9)
Fa=T-DEPa=T-Htan(θ/2)…(10)
Fb=T+DEPb=T+Htan(θ/2)…(11)
次に、実施例2に係る放射線断層撮影装置1Aの動作について説明する。実施例2に係る放射線断層撮影装置における動作の工程のフローチャートは実施例1と同様である。なお、X線管3およびFPD5は図12において実線で示される位置にあるものとする。
まず操作者はFPD5の撮影可能範囲を算出する。すなわち操作者は入力部33を操作して撮影距離G、照射振り角度θ、および断層面高さHのパラメータを入力する。入力されたパラメータは撮影範囲算出部35へ送信される。また、床面WからX線焦点3aまでの高さSの最大値Smax、および高さSの最小値Sminのパラメータが記憶部37から撮影範囲算出部35へ送信される。
撮影範囲算出部35がFPD5の撮影可能範囲FPを算出した後、FPD5の位置の移動を行う。そこでまず操作者はFPD5の側へ移動し、ブレーキ21を操作してオフの状態にする。そして図13に示すように、操作者は被検体Mの関心部位に応じて、FPD5を破線で示す位置から実線で示す位置へ手動で移動させる。
FPD5の位置の移動が終了した後、次にX線断層撮影の準備を行う。すなわち操作者は入力部33を操作して、X線断層撮影の準備を行う指示を入力する。入力部33に入力される指示に従って、主制御部31からX線管移動機構15、X線管回転機構19、支持部移動機構20、およびFPD移動機構23へ制御信号が出力される。
X線断層撮影の準備が完了した後、次にX線画像の生成を行う。すなわち操作者は入力部33を操作して、X線の照射を開始する指示を入力する。X線管3はX線管移動機構15によって、図15において実線で示される照射開始位置から、破線で示される照射終了位置へ直進移動するように制御される。FPD5はFPD移動機構23によって、実線で示される検出開始位置から、破線で示される検出終了位置へ直進移動するように制御される。
一連のX線画像が生成されると、断層画像再構成部27は一連のX線画像に係る画像情報を再構成する。X線画像に係る画像情報の再構成によって、所望の裁断位置における被検体MのX線断層画像データを取得できる。モニタ29は断層画像再構成部27において取得されたX線断層画像データを表示させる。
このように、実施例2に係る放射線断層撮影装置1Aにおいて、撮影範囲算出部35はX線断層撮影を行う前にFPD5の撮影可能範囲を算出する。FPD5の撮影可能範囲は
撮影距離G、照射振り角度θ、断層面高さH、およびX線管3の移動可能範囲SPに基づいて算出される。撮影距離G、照射振り角度θ、および断層面高さHは、X線断層画像の撮影を行うたびに操作者が予め任意に決定するパラメータである。そしてX線管3の移動可能範囲SPは放射線断層撮影装置1に対して予め定められたパラメータである。従って操作者はこれらのパラメータに基づいて、FPD5の撮影可能範囲をX線管の移動開始前に予め算出できる。
このような実施例3に係る放射線断層撮影装置1Cにおいて、撮影範囲算出部35がFPD5の撮影可能範囲を算出する方法を説明する。なお、床面Wから撮影準備位置Afまでの高さをSaf、床面Wから撮影終了位置Bfまでの高さをSbfとする。
Saf=F+DAC+R1=F+Gtan(θ/2)+R1…(12)
Sbf=F-DBC-R2=F-Gtan(θ/2)-R2…(13)
Smax-Gtan(θ/2)-R1≧F≧Smin+Gtan(θ/2)+R2…(14)
Saf=T+DAC+R1=T+(G-H)tan(θ/2)+R1…(15)
Sbf=T-DBC-R2=T-(G-H)tan(θ/2)-R2…(16)
Smax-(G-H)tan(θ/2)-R1≧T…(17)
Smin+(G-H)tan(θ/2)+R2≦T…(18)
このように、撮影範囲算出部35は撮影距離Gなどのパラメータを用いてFPD5の撮影可能範囲FPを算出できる。撮影可能範囲FPの算出に用いられるパラメータはいずれもX線断層撮影を行う前に予め定めることのできるパラメータである。従って操作者は予め定められているパラメータ群を用いることにより、図19に示すような実施例3についても、X線断層撮影を行う前にFPD5の撮影可能範囲FPを予め算出することができる。
3 …X線管(放射線源)
5 …FPD(放射線検出手段)
7 …X線管支持部
11 …コリメータ
15 …X線管移動機構(放射線源移動手段)
17 …X線照射制御部(放射線照射制御手段)
19 …X線管回転機構
23 …FPD移動機構(検出器移動手段)
25 …画像生成部(画像生成手段)
27 …断層画像再構成部(断層画像取得手段)
29 …モニタ
31 …主制御部(検出器移動制御手段)
33 …入力部
35 …撮影可能範囲算出部(撮影可能範囲算出手段)
37 …記憶部
39 …X線管検出部
41 …FPD検出部(検出器位置算出手段)
43 …警告音発信部(警告手段)
Claims (7)
- 被検体に放射線を照射する放射線源と、
被検体を透過した放射線を検出する放射線検出手段と、
前記放射線源を被検体の体軸方向に移動させる放射線源移動手段と、
前記放射線源移動手段が前記放射線源を移動させている間に、前記放射線源に放射線照射を繰り返させる制御を行う放射線照射制御手段と、
前記放射線源による放射線照射毎に前記放射線検出手段が出力する検出信号を用いて放射線画像を生成する画像生成手段と、
前記画像生成手段が生成した複数の放射線画像を再構成させて放射線断層画像を取得する断層画像取得手段と、
前記放射線源の焦点から前記放射線検出手段の検出面までの距離である撮影距離、前記放射線照射制御手段が前記放射線源に放射線照射を繰り返させる間における前記放射線源の振り角度である照射振り角度、および前記放射線源の移動可能範囲からなるパラメータ群に基づいて、前記放射線源が前記放射線源の移動可能範囲を逸脱することなく前記放射線断層画像を取得できる前記放射線検出手段の位置の範囲である、前記放射線検出手段の撮影可能範囲を算出する撮影可能範囲算出手段とを備えていることを特徴とする放射線断層撮影装置。 - 被検体に放射線を照射する放射線源と、
被検体を透過した放射線を検出する放射線検出手段と、
前記放射線源を被検体の体軸方向に移動させる放射線源移動手段と、
前記放射線源移動手段が前記放射線源を移動させている間に、前記放射線源に放射線照射を繰り返させる制御を行う放射線照射制御手段と、
前記放射線源による放射線照射毎に前記放射線検出手段が出力する検出信号を用いて放射線画像を生成する画像生成手段と、
前記画像生成手段が生成した複数の放射線画像を再構成させて放射線断層画像を取得する断層画像取得手段と、
前記放射線検出手段を、前記被検体を挟んで前記放射線源と対向させた状態で前記放射線源移動手段が前記放射線源を移動させる方向と逆向きに移動させる検出器移動手段と、
前記放射線源の焦点から前記放射線検出手段の検出面までの距離である撮影距離、前記放射線照射制御手段が前記放射線源に放射線照射を繰り返させる間における前記放射線源の振り角度である照射振り角度、前記放射線源の移動可能範囲、および前記放射線検出手段の検出面から断層中心までの距離である断層面高さからなるパラメータ群に基づいて、前記放射線源が前記放射線源の移動可能範囲を逸脱することなく前記放射線断層画像を取得できる前記放射線検出手段の位置の範囲である、前記放射線検出手段の撮影可能範囲を算出する撮影可能範囲算出手段とを備えていることを特徴とする放射線断層撮影装置。 - 請求項1または請求項2に記載の放射線断層撮影装置において、
前記パラメータ群は、前記放射線源が加速移動する距離である、前記放射線源の撮影準備位置から照射開始位置までの加速距離と、前記放射線源が減速移動する距離である、前記放射線源の照射終了位置から撮影終了位置までの減速距離とをさらに含む放射線断層撮影装置。 - 請求項1ないし請求項3のいずれかに記載の放射線断層撮影装置において、
前記パラメータ群を入力する入力部を備え、
前記撮影可能範囲算出手段は前記入力部に前記パラメータ群が入力される度に、前記入力部に入力された前記パラメータ群に基づいて前記放射線検出手段の撮影可能範囲を算出する放射線断層撮影装置。 - 請求項1ないし請求項4のいずれかに記載の放射線断層撮影装置において、
前記放射線検出手段の位置を算出する検出器位置算出手段を備える放射線断層撮影装置。 - 請求項5に記載の放射線断層撮影装置において、
前記検出器位置算出手段が算出する前記放射線検出手段の位置が前記放射線検出手段の撮影可能範囲外である場合に警告を行う警告手段を備える放射線断層撮影装置。 - 請求項5または請求項6に記載の放射線断層撮影装置において、
前記検出器位置算出手段が算出する前記放射線検出手段の位置が前記放射線検出手段の撮影可能範囲外である場合に、前記放射線検出手段を前記撮影可能範囲へ移動するように前記検出器移動手段を制御する検出器移動制御手段を備える放射線断層撮影装置。
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JP7208874B2 (ja) | 2019-08-27 | 2023-01-19 | 富士フイルム株式会社 | 撮影制御装置、方法およびプログラム |
Also Published As
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CN106456086A (zh) | 2017-02-22 |
CN106456086B (zh) | 2019-10-08 |
JPWO2015166575A1 (ja) | 2017-04-20 |
JP6057020B2 (ja) | 2017-01-11 |
US10398401B2 (en) | 2019-09-03 |
US20170055936A1 (en) | 2017-03-02 |
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