WO2011013771A1 - 放射線撮像装置及び放射線による撮像方法 - Google Patents
放射線撮像装置及び放射線による撮像方法 Download PDFInfo
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Definitions
- the present invention relates to a radiation imaging apparatus and a radiation imaging method, and in particular, reconstructs tomographic image data by processing radiation data obtained by scanning an imaging target from a number of directions according to a tomosynthesis method (tomosynthesis),
- the present invention relates to a radiation imaging apparatus that identifies a three-dimensional position of an internal structure of an imaging target using the tomographic image data and an imaging method using radiation.
- This panoramic imaging apparatus When the tomosynthesis method is applied to dentistry, it is usually put into practical use as a panoramic imaging device that obtains a panoramic image in which a curved dentition is developed in a two-dimensional plane.
- This panoramic imaging apparatus normally has a pair of an X-ray tube and an X-ray detector having pixels extending in the longitudinal direction around the oral cavity of a subject, and a constant trajectory along a dentition whose rotation center is assumed.
- a mechanism for rotating the center of rotation in a complex manner is provided.
- This constant trajectory is a trajectory for focusing on a 3D reference tomographic plane set in advance along a dentition regarded as a standard shape and size.
- Patent Document 7 In order to overcome such a problem, an apparatus described in Patent Document 7 is provided.
- the position of the dentition in the depth direction and the gain are measured in advance using a phantom. Further, a focus optimization image of the 3D reference tomographic plane is formed based on the tomosynthesis method using the collected frame data. Further, a partial area is designated on the focus optimized image using the ROI, and an optimally focused image at an arbitrary position in the front-rear direction of this partial area (the front-rear direction of the dentition connecting the X-ray tube and the X-ray detector). Is obtained based on the tomosynthesis method using the already collected frame data and gain. As described above, data collection is performed once while focusing on the 3D reference tomographic plane, and the collected frame data can be used for the optimum focus image of the subsequent partial region.
- the above-mentioned inconvenience is promoted by the fact that the enlargement ratio in the vertical and horizontal directions (vertical direction and width direction of the dentition) of the image varies depending on the change in the position of the rotation center during scanning.
- the enlargement ratio refers to the ratio between the actual size of a tooth and the size of an enlarged projection image created by the shadow of the tooth on the X-ray incident surface of the detector. This is because the X-ray irradiation source of the X-ray tube is so small as to be regarded as a point, and X-rays are irradiated radially from the point-like X-ray source.
- the dentition existing on the 3D tomographic plane is reconstructed based on the tomosynthesis method
- the image in the horizontal direction is the same in every position, but the enlargement remains in the vertical direction.
- the reconstructed panoramic image is a vertically longer image than the actual dentition.
- the extent of such enlargement that is, the length of the image, is different in the shape of the teeth in the vertical direction between the position near the front teeth and the positions near both molars (so-called back teeth). It is a distortion between teeth.
- image distortion between dentition portions due to enlargement in the vertical and horizontal directions becomes more remarkable.
- the coefficient for reducing the size in the vertical direction is restored so that the aspect ratio is the same at least at the center of the front tooth.
- post-processing is applied to the constituent images.
- the height of the tooth of the molar portion in the panoramic image is drawn smaller than the actual size. That is, there was still image distortion in each tooth due to the difference in magnification.
- the present invention has been made in view of the above circumstances, and optimally focuses the entire image area in a state in which the actual state (position, shape) of the imaging region is depicted three-dimensionally with higher accuracy, and is different in magnification rate. It is an object of the present invention to provide a radiation imaging method capable of providing a three-dimensional optimum focus image in which image distortion due to the above is almost eliminated.
- the present invention provides a radiation imaging apparatus, a data processing apparatus, an imaging method using radiation, and a computer program as its category.
- the radiation imaging apparatus includes a radiation emission source that emits radiation, a radiation detector that outputs two-dimensional data of digital electricity corresponding to the radiation when the radiation is incident, and the radiation emission.
- a pair of a source and the radiation detector, moving means for moving the radiation detector or object relative to the remaining elements, and the data output from the radiation detector during movement by the moving means Data collecting means for collecting image data in units of frames, and using the data collected by the data collecting means to optimize the focus of the imaging part of the object and reflect the actual size and shape of the imaging part
- the gist of the present invention is to provide image creation means for creating a three-dimensional optimum focus image.
- the data processing apparatus includes a radiation emission source that emits radiation, a radiation detector that outputs two-dimensional data of a digital quantity corresponding to the radiation when the radiation is incident, and the radiation emission source. And a pair of the radiation detector, a moving means for moving the radiation detector or the object relative to the remaining elements, and the data output from the radiation detector during the movement by the moving means is a frame.
- an imaging method using radiation includes a radiation source and a radiation detector that outputs two-dimensional data of a digital electric quantity corresponding to the radiation when the radiation is incident from the radiation source in units of frames.
- the gist is that
- the computer program is a program stored in advance in a memory and readable from the memory, and a radiation emission source that emits radiation and a digital that corresponds to the radiation when the radiation is incident.
- a radiation detector that outputs two-dimensional data of an electric quantity in units of frames, a pair of the radiation emission source and the radiation detector, a moving means for moving the detector or an object with respect to the remaining elements;
- a program for causing a computer to process the data output from a system including data collection means for collecting the data output from the radiation detector in units of frames during movement by the moving means.
- the program includes the step of reconstructing, as a reference plane image, a projection image obtained by projecting a desired reference tomographic plane of the imaging region of the object onto the detection plane of the detector using the data; Setting a plurality of tomographic planes along the reference tomographic plane in a direction opposite to the reference tomographic plane, and calculating each pixel value of the plurality of tomographic planes using pixel values of the reference tomographic plane Identifying an optimally focused sample position of the imaging region using image data of the reference tomographic plane and the plurality of tomographic planes to which the pixel values are given, and the identified sample position Providing pixels from the X-ray tube on the line of sight facing the detector via each sample position and based on pixel values of corresponding sample points of the reference plane image; Determining a position of the imaging region by pattern recognition of frequency characteristics of pixel values of the reference tomographic plane and the plurality of tomographic planes at the sample position to which the pixel value is assigned; and A step of removing a
- the focus of the imaging part of the object is optimized using the collected data, and the imaging is performed. It is created as a three-dimensional optimal focus image reflecting the actual size and shape of the part.
- the three-dimensional optimum that optimally focuses the entire image area in a state in which the actual state (position, shape) of the object to be imaged is three-dimensionally rendered with higher accuracy, and eliminates almost all image distortion due to the difference in magnification.
- the focus image is provided with a three-dimensional panoramic image.
- FIG. 1 is a perspective view showing an outline of the overall configuration of a panoramic imaging apparatus using X-rays as a radiation imaging apparatus according to an embodiment of the present invention.
- FIG. 2 is a rotation center when a dentition of a subject targeted by the panoramic imaging apparatus according to the embodiment, a 3D reference tomographic plane set in the dentition, and a pair of an X-ray tube and a detector rotate.
- FIG. 3 is a perspective view for explaining the geometry of the X-ray tube, 3D reference tomographic plane, and detector in the panoramic imaging apparatus.
- FIG. 4 is a block diagram for explaining an outline of an electrical configuration of the panoramic imaging apparatus.
- FIG. 1 is a perspective view showing an outline of the overall configuration of a panoramic imaging apparatus using X-rays as a radiation imaging apparatus according to an embodiment of the present invention.
- FIG. 2 is a rotation center when a dentition of a subject targeted by the panoramic imaging apparatus according to the embodiment, a 3D reference tomographic plane set in
- FIG. 5 is a flowchart showing an outline of processing for imaging that is executed in cooperation by the controller of the panoramic imaging apparatus and the image processor.
- FIG. 6 is a diagram for explaining the positional relationship among an X-ray tube, a 3D reference tomographic plane, a rotation center, and a detector.
- FIG. 7 is a graph illustrating the relationship between frame data and the panorama image mapping position.
- FIG. 8 is a diagram schematically illustrating an example of a reference panoramic image.
- FIG. 9 is a diagram schematically illustrating an example of an image when an ROI is set for a reference panoramic image.
- FIG. 10 is a flowchart for explaining the outline of processing for identifying the actual position and shape of a tooth executed by the image processor.
- FIG. 6 is a diagram for explaining the positional relationship among an X-ray tube, a 3D reference tomographic plane, a rotation center, and a detector.
- FIG. 7 is a graph illustrating the relationship between frame data and the panorama image mapping position.
- FIG. 11 is a diagram for explaining a difference in projection angle from the same position in the Z-axis direction on the 3D panoramic image to the X-ray tube according to a change in the rotation center of the pair of the X-ray tube and the detector.
- FIG. 12 is a diagram schematically illustrating an example of a 3D reference image.
- FIG. 13 is a perspective view illustrating a plurality of parallel tomographic planes added to the 3D reference tomographic plane.
- FIG. 14 shows differences in positions on a plurality of tomographic planes when projected onto the X-ray tube from the same position in the Z-axis direction on the 3D panoramic image as the rotation center of the pair of the X-ray tube and the detector changes. Illustration to explain.
- FIG. 16 is a graph illustrating the result of frequency analysis in the process of specifying the optimum focus position.
- FIG. 17 is a graph illustrating an example of the position of the tomographic plane of the optimum focus in the process of specifying the optimum focus position.
- FIG. 18 is a graph illustrating a frequency characteristic pattern that changes according to a tomographic plane position.
- FIG. 19 is a diagram illustrating a state where the actual tooth position is deviated from the 3D reference tomographic plane.
- FIG. 20 is a diagram illustrating a state in which the tooth is shifted from the position of the 3D reference tomographic plane to the actual position according to the magnification ratio.
- FIG. 21 is a diagram for explaining a state in which the tooth is shifted from the position of the 3D reference tomographic plane to the actual position according to the magnitude of the enlargement ratio.
- FIG. 22 is a diagram illustrating a state in which teeth are shifted from the position of the 3D reference tomographic plane to the actual position according to the magnitude of the enlargement ratio.
- FIG. 23 is a perspective view illustrating processing for moving a processing point on the 3D reference image for the position identification position.
- FIG. 24 is a perspective view illustrating identification of a tomographic plane position of an optimum focus specified for each processing point and abnormal identification thereof.
- FIG. 25 is a diagram schematically showing a 3D autofocus image created by identifying the optimum focus tomographic plane position and smoothing.
- FIG. 26 is a diagram for explaining the concept of processing for projecting a 3D autofocus image onto a 3D reference tomographic plane.
- FIG. 27 is a schematic diagram schematically illustrating an image projected on a 3D reference tomographic plane and an ROI set there.
- FIG. 28 is a diagram for explaining the concept of processing for projecting a 3D autofocus image onto a two-dimensional surface of a reference panoramic image.
- FIG. 29 is a diagram schematically illustrating a 2D reference image and an ROI set there.
- FIG. 30 is a diagram for explaining landmarks described as modified examples and usage examples thereof.
- FIG. 31 is a view for explaining profiles of frequency characteristics of various landmarks.
- FIG. 32 is a diagram for explaining landmarks described as another modification example and usage examples thereof.
- FIG. 33 is a diagram for explaining landmarks described as still another modification example and usage examples thereof.
- FIG. 1 shows the external appearance of such a panoramic imaging device 1.
- This panoramic imaging apparatus 1 scans the subject's jaw with X-rays, and identifies the actual position (actual position) of a three-dimensional dentition in the jaw from the digital X-ray transmission data. In addition, a panoramic image that compensates for variations (differences) in the enlargement ratio described later of the dentition is created.
- this panoramic imaging apparatus 1 can provide epoch-making performance, such as being able to perform various forms of display and measurement from such panoramic images.
- an X-ray exposure dose can be reduced for the subject, and an imaging device that is easy for the operator to use can be provided. To obtain the basic performance described above, the tomosynthesis method is used.
- the panoramic imaging apparatus 1 includes a housing 11 that collects data from a subject (patient) P, for example, in a standing posture of the subject P, and data collection performed by the housing 11. Consists of a computer that controls and captures the collected data to create a panoramic image and performs post-processing of the panoramic image interactively or automatically with an operator (doctor, technician, etc.) And a control / arithmetic unit 12.
- the housing 11 includes a stand unit 13 and a photographing unit 14 that can move up and down with respect to the stand unit 13.
- the imaging unit 14 is attached to the support column of the stand unit 13 so as to be movable up and down within a predetermined range.
- an XYZ orthogonal coordinate system having the longitudinal direction of the stand unit 13, that is, the vertical direction as the Z axis is set.
- the horizontal axis direction is expressed as j axis
- the photographing unit 14 includes a vertical movement unit 23 having a substantially U-shape when viewed from the side, and a rotation unit 24 supported by the vertical movement unit 23 so as to be rotatable (rotatable).
- the vertical movement unit 23 is arranged in the Z-axis direction (vertical axis direction) over a predetermined range in the height direction through a vertical drive mechanism (for example, a motor and a rack and pinion) (not shown) installed on the stand unit 13. It can be moved. A command for this movement is issued from the control / arithmetic unit 12 to the vertical movement drive mechanism.
- the vertical movement unit 23 is substantially U-shaped when viewed from one side surface thereof, and includes an upper arm 23A and a lower arm 23B on each of the upper and lower sides, and upper and lower arms 23A and 23B.
- the connecting vertical arm 23C is integrally formed.
- the vertical arm 23C is supported by the above-described stand portion 13 so as to be movable up and down.
- the upper arm 23A and the vertical arm 23C cooperate to form a photographing space (real space).
- a rotational drive mechanism 30A for example, an electric motor and a reduction gear
- the rotational drive mechanism 30A receives a rotational drive command from the control / arithmetic unit 12.
- the output shaft of the rotation drive mechanism 30A that is, the rotation shaft of the electric motor is disposed so as to protrude downward (downward in the Z-axis direction) from the upper arm 23A, and the rotation unit 24 can rotate on this rotation shaft. Is bound to. That is, the rotation unit 24 is suspended by the vertical movement unit 23 and is rotated by being energized by the drive of the rotation drive mechanism 30A.
- the rotation drive mechanism 30A is connected to the movement mechanism 30B.
- the moving mechanism 30B is composed of an electric motor, a gear, etc. (not shown).
- the moving mechanism 30B also operates in response to a rotation driving command from the control / arithmetic unit 12, and is configured to be able to move the rotation driving mechanism 30A, that is, the rotation unit 24 along the XY plane.
- the locus of the rotation center of a pair of an X-ray tube and a detector which will be described later, can be moved two-dimensionally along a constant trajectory within a predetermined range along the XY plane.
- the lower arm 23B is extended to have a predetermined length in the same direction as the upper arm 23A, and a chin rest 25 is formed at the tip thereof.
- a bite block 26 (or simply called a bite) is detachably attached to the chin rest 25.
- the subject P holds this byte block 26.
- the chin rest 25 and the bite block 26 serve to fix the oral cavity of the subject P.
- the rotating unit 24 has an appearance that is formed in a substantially U shape when viewed from one side surface in the state of use, and is rotatable to the motor output shaft of the upper arm 23A so that its open end can be rotated downward. It is attached. Specifically, a horizontal arm 24A that rotates (rotates) in the horizontal direction, that is, substantially parallel in the XY plane, and left and right vertical arms (first axis) extending downward (Z-axis direction) from both ends of the horizontal arm 24A. Vertical arm, second vertical arm) 24B, 24C. The horizontal arm 24 and the left and right first and second arms 24B and 24C are located in a photographing space (actual space) and are driven and operated under the control of the control / arithmetic apparatus 12.
- the X-ray tube 31 as a radiation emission source is equipped at the lower end inside the first vertical arm 24B.
- the X-ray tube 31 is constituted by a rotating anode X-ray tube, for example, and radiates X-rays radially from the target (anode) toward the second vertical arm 24C.
- the focal point of the electron beam colliding with the target is as small as about 0.5 mm to 1 mm in diameter, and therefore the X-ray tube 31 has a point-like X-ray source.
- a slit-shaped collimator that narrows a relatively thin beam-shaped X-ray incident on the detector 32 into an actual collection window (for example, a window having a width of 5.0 mm). 33 is attached.
- this collimator 33 may include this collimator 33 in the element which comprises a radiation emission source.
- a digital X-ray detector 32 in which X-ray detection elements as radiation detection means are arranged two-dimensionally (for example, in a 64 ⁇ 1500 matrix) is provided at the lower end of the second vertical arm 24C. X-rays incident from this incident window are detected.
- the detector 32 has a vertically long detection surface (for example, 6.4 mm wide ⁇ 150 mm long) made of CdTe. Since this embodiment employs the tomosynthesis method, the detector 32 must have a plurality of X-ray detection elements also in the lateral (width) direction.
- the detector 32 is arranged in the vertical direction with its vertical direction coinciding with the Z-axis direction.
- the effective width in the lateral direction of the detector 32 is set to, for example, about 5.0 mm by the collimator 33 described above.
- the detector 32 can collect incident X-rays as image data of digital electric quantity corresponding to the amount of the X-rays at a frame rate of 300 fps (one frame is, for example, 64 ⁇ 1500 pixels), for example.
- this collected data is referred to as “frame data”.
- the X-ray tube 31 and the detector 32 are positioned so as to face each other with the oral cavity of the subject P interposed therebetween, and are driven so as to rotate around the oral cavity as a unit.
- this rotation is not a rotation that draws a simple circle. That is, the pair of the X-ray tube 31 and the detector 32 has a mountain-shaped constant trajectory in which the rotation center RC of the pair is formed by connecting two circular arcs inside the substantially horseshoe-shaped dentition as shown in FIG. Is driven to rotate.
- This constant trajectory is focused on a tomographic plane (hereinafter referred to as a 3D reference tomographic plane) SS along the standard shape and size of the dentition of the oral cavity and follows the 3D reference tomographic plane SS.
- a 3D reference tomographic plane This is a pre-designed track.
- the X-ray focal point follows the 3D reference tomographic plane SS
- the X-ray tube 31 and the detector 32 do not necessarily rotate at the same angular velocity when viewed from the 3D reference tomographic plane SS. That is, this rotation can be referred to as “movement along the dentition”, and is rotated while appropriately changing the angular velocity.
- the X-ray tube 31 and the detector 32 need to move while being positioned so as to face each other with the oral cavity of the subject P interposed therebetween.
- the facing state does not necessarily require that the X-ray tube 31 and the detector 32 face each other.
- the X-ray tube 31 and the detector 32 may rotate independently of each other and include a rotational position where X-ray irradiation is oblique while sandwiching the oral cavity of the subject P. .
- the locus on the XY plane when the 3D reference tomographic plane SS is viewed from the Z-axis direction is substantially horseshoe-shaped as described above, and an example is shown in FIG.
- the trajectory of this 3D reference fault plane SS is also known, for example, from the document “R. Molteni,“ A universal test phantom for dental panoramic radiography ”MedicaMudi, vol. 36, no.3, 1991”.
- the spatial position information of the 3D reference tomographic plane SS is stored in the ROM 61 in advance.
- the 3D reference tomographic plane SS may be set as a known plane as described above, but may be set in advance according to the individual of the subject.
- a desired three-dimensional section created from a surface image photographed by a camera, an MRI (magnetic resonance imaging) apparatus, a CT (computer tomography) scanner, or a medical modality including an ultrasonic diagnostic apparatus. It may be either a desired three-dimensional section of the subject imaged or a desired three-dimensional section determined from the three-dimensional data of the subject imaged by the medical modality.
- These 3D reference tomographic planes SS may be set using a known method and stored in the ROM 61 in advance.
- the geometric positional relationship between the X-ray tube 31, the 3D reference tomographic plane SS, the detector 32, the rotation axis AXz, and the rotation center RC through which the rotation axis AXz passes is as shown in FIG.
- the 3D reference tomographic plane SS is parallel to the entrance of the detector 32 (X-ray detection plane Ldet: see FIG. 6), is a curved cross section along the Z-axis direction, and is elongated and has a rectangular shape when developed in two dimensions. It is set as a cross section.
- FIG. 4 shows an electrical block diagram for control and processing of this panoramic imaging apparatus.
- the X-ray tube 31 is connected to the control / arithmetic apparatus 12 via a high voltage generator 41 and a communication line 42
- the detector 32 is connected to the control / arithmetic apparatus 12 via a communication line 43.
- the high voltage generator 41 is provided in the stand unit 13, the vertical movement unit 23, or the rotation unit 24. It is controlled according to the shooting conditions and the sequence of exposure timing.
- the control / arithmetic unit 12 is composed of, for example, a personal computer capable of storing a large amount of image data in order to handle a large amount of image data. That is, the control / arithmetic unit 12 has, as its main components, interfaces 51, 52, 62, a buffer memory 53, an image memory 54, a frame memory 55, which are connected to each other via an internal bus 50.
- An image processor 56, a controller (CPU) 57, and a D / A converter 59 are provided.
- An operation device 58 is communicably connected to the controller 57, and a D / A converter 59 is also connected to a monitor 60.
- the interfaces 51 and 52 are connected to the high voltage generator 41 and the detector 32, respectively, and communicate control information and collected data exchanged between the controller 57 and the high voltage generator 41 and the detector 32. Mediate.
- Another interface 62 connects the internal bus 50 and a communication line, and the controller 57 can communicate with an external device.
- the controller 57 can also capture an intraoral image captured by an external intraoral X-ray imaging apparatus, and convert a panoramic image captured by the present imaging apparatus to an external device according to, for example, DICOM (Digital Imaging and Communications Communications in Medicine) standards. It can be sent to the server.
- DICOM Digital Imaging and Communications Communications in Medicine
- the buffer memory 53 temporarily stores digital frame data received from the detector 32 via the interface 52.
- the image processor 56 is placed under the control of the controller 57 and interactively creates a panoramic image of a predetermined 3D reference tomographic plane provided by the apparatus side and processes for subsequent use of the panoramic image with the operator. It has a function to execute.
- a program for realizing this function is stored in the ROM 61 in advance. Therefore, the ROM 61 functions as a recording medium that stores the program according to the present invention. This program may be stored in the ROM 61 in advance. However, in some cases, the program may be installed in a recording medium such as a RAM (not shown) via a communication line or a portable memory. .
- the 3D reference tomographic plane described above is prepared in advance on the apparatus side.
- the 3D reference tomographic plane may be selected before photographing from a plurality of tomographic planes prepared in advance on the apparatus side.
- the selection operation enables the position of the 3D reference tomographic plane to be changed within a certain range in the depth (front and back) direction of the dentition. Also good.
- the frame data and image data processed by the image processor 56 or being processed are stored in the image memory 54 so as to be readable and writable.
- a large-capacity recording medium nonvolatile and readable / writable
- the frame memory 55 is used to display reconstructed panoramic image data, post-processed panoramic image data, and the like.
- the image data stored in the frame memory 55 is called by the D / A converter 59 at a predetermined cycle, converted into an analog signal, and displayed on the screen of the monitor 60.
- the controller 57 controls the overall operation of the constituent elements of the apparatus in accordance with a program responsible for the overall control and processing stored in the ROM 61 in advance. Such a program is set so as to interactively receive operation information for each control item from the operator. Therefore, the controller 57 is configured to be able to execute collection (scanning) of frame data and the like, as will be described later.
- the patient places the jaw at the position of the chin rest 25 in the standing or sitting posture, holds the bite block 26, and presses the forehead against the headrest 28.
- the position of the patient's head (jaw) is fixed at substantially the center of the rotation space of the rotation unit 24.
- the rotation unit 24 rotates around the patient's head along the XY plane and / or along an oblique plane on the XY plane (see arrows in FIG. 1). .
- the high voltage generator 41 supplies a high voltage for exposure (specified tube voltage and tube current) to the X-ray tube 31 in a pulse mode with a predetermined cycle.
- the X-ray tube 31 is driven in the pulse mode.
- pulsed X-rays are emitted from the X-ray tube 31 at a predetermined cycle.
- the X-rays pass through the patient's jaw (dental portion) located at the imaging position and enter the detector 32.
- the detector 32 detects incident X-rays at a very high frame rate (for example, 300 fps), and sequentially outputs corresponding two-dimensional digital data (for example, 64 ⁇ 1500 pixels) in units of frames. Output.
- the frame data is temporarily stored in the buffer memory 53 via the communication line 43 and the interface 52 of the control / arithmetic apparatus 12. The temporarily stored frame data is then transferred to the image memory 53 and stored.
- the image processor 56 reconstructs (creates) a tomographic image focused on the 3D reference tomographic plane SS as a panoramic image (reference panoramic image) using the frame data stored in the image memory 53. That is, this reference panoramic image is defined as “a panoramic image when it is assumed that a dentition is present on the 3D reference tomographic plane SS”.
- the image processor 56 performs processing such as creating a reference three-dimensional (3D) image and a three-dimensional (3D) autofocus image using the reference panorama standard image. An outline of this processing is shown in FIG.
- the 3D reference image is defined as “a three-dimensional image when it is assumed that a dentition is present on the 3D reference tomographic plane SS”.
- the 3D autofocus image is defined as “a surface image (pseudo 3D surface image) in which the dentition is automatically optimally focused using frame data or reference panoramic image data from the 3D reference image”. That is, this 3D autofocus image is an optimally focused surface image that is less blurred and accurately represents the actual position and actual size of the dentition.
- the 3D autofocus image is an image that takes into account the fact that it is mostly different for each subject.
- the dentition of each subject is not along the 3D reference tomographic plane SS (see FIG. 6), and is partially or entirely offset from the 3D reference tomographic plane SS or from that plane. It is tilted.
- the 3D autofocus image automatically and accurately identifies the actual three-dimensional spatial position and shape of the dentition of each subject, and automatically displays the actual dentition shape from the identification result. To be created.
- X-rays emitted from the X-ray tube 31 (functioning as a pointed X-ray source) pass through the oral cavity of the subject P and are detected by a vertically long detector 32 having a certain length in the Z-axis direction. Is done. For this reason, the X-ray irradiation direction becomes oblique as shown in FIGS. Therefore, the ratio between the actual size of the tooth and the size of the projected image formed by the shadow of the tooth on the X-ray incident surface Ldet of the detector 32 (in this embodiment, this ratio is called “magnification ratio”) is the center of rotation. It changes according to the position of RC. That is, in the example of FIG.
- the ratio between the actual tooth height P 1 real and the height P 1 det on the X-ray incident surface Ldet is rotated. It changes according to the position of the center RC.
- the position of the rotation center RC is set in advance so as to change during one scan (data collection) as illustrated in FIG. The reason for this is as follows. As shown in FIG. 6, the distance D all between the X-ray tube 31 and the detector 32 is kept constant, and the distances D1 and D2 from the rotation center RC to the X-ray tube 31 and the detector 32 are also constant. Retained.
- the trajectory at the position of the rotation center RC is an example with respect to the dentition curved in a horseshoe shape during one scan. As described above, it is designed to change into a mountain shape (see FIG. 2).
- the distance D3 from the rotation center RC to the 3D reference tomographic plane SS and the distance D4 from the detector 32 to the 3D reference tomographic plane SS change as the scan proceeds.
- the rotation center RC approaches or moves away from the dentition, so that the X-ray tube 31 also approaches or moves away from the dentition.
- the X-ray source of the X-ray tube 31 is regarded as a point-like shape, the projection onto the detection surface Ldet becomes closer as the X-ray tube 31 is closer to the dentition even if the teeth have the same height. The image gets bigger. That is, the enlargement rate is large.
- the center of rotation RC is closer to the dentition when scanning the anterior teeth than when scanning the molar portion, and the enlargement ratio is correspondingly increased.
- the distance d1 when scanning the anterior tooth portion for example, when the X-ray irradiation direction is 0 °
- the distance d2 when scanning the molar portion for example, when the X-ray irradiation direction is 60 °, 75 °
- the trajectory of the rotation center RC shown in FIG. 2 is merely an example, but in the case of a panoramic imaging apparatus that scans while focusing on the 3D reference tomographic plane SS, the rotation center RC approaches and moves away from the dentition. This is the case.
- the conventional panoramic image is created without considering the above-described problem due to the enlargement ratio and the deviation of the actual dentition from the 3D reference tomographic plane SS. For this reason, quantitative structural analysis from the conventional panoramic image is very difficult, and even if the dentition is in various shapes and positions for each subject, teeth in the dentition of the same subject A panoramic imaging device that can capture images with high accuracy regardless of the position of the camera has been desired.
- the panoramic imaging apparatus eliminates image distortion caused by the magnification rate being different for each portion even in the same dentition, and the three-dimensional dentition of the actual subject.
- One of the features is that the spatial position (including shape) is automatically and accurately identified. As a result, it is possible to provide a three-dimensional panoramic image with extremely high position (shape) identification accuracy that has not existed before.
- the tomosynthesis method (tomosynthesis) is used to obtain an image of the tomographic plane. That is, among frame data (pixel data) collected at a constant rate by scanning, a plurality of frame data determined for each position of the locus projected on the XY plane of the three-dimensional 3D reference tomographic plane is an amount corresponding to the position. Only a shift (add & add) is performed by shifting each other. For this reason, “optimal focus” in this embodiment means “the focus is best, and there is little out of focus”, and the portion of interest has better resolution than other portions, or Says that the overall resolution of the image is higher.
- the data is stored in the image memory 54 and displayed on the monitor 60 in an appropriate manner.
- the operator's intention given from the operation device 58 is reflected in the display mode and the like.
- this processing includes data collection by scanning, reconstruction of a reference panoramic image as preprocessing, creation of a three-dimensional autofocus image (surface image) as main processing, and three-dimensional autofocus thereof. Display and measurement according to various aspects using an image are included.
- the controller 57 reads the position information of the 3D reference tomographic plane SS from the ROM 61 (step S0).
- the 3D reference tomographic plane SS may be a statistically determined cross section, or may be a cross section set in advance by each subject.
- the controller 57 commands a scan for data collection in response to an instruction from the operator given through the operation device 58 (step S1).
- the rotation drive mechanism 30A, the moving mechanism 30B, and the high voltage generator 41 are driven in accordance with a preset control sequence.
- the pulsed (or continuous wave) X-ray is applied to the X-ray tube 31 during the rotating operation. Exposure is performed at a predetermined cycle (or continuously).
- the pair of the X-ray tube 31 and the detector 32 is rotationally driven under a predetermined driving condition so as to optimally focus the 3D reference tomographic plane SS (see FIG. 6) as described above.
- the X-rays exposed from the X-ray tube 31 pass through the subject P and are detected by the detector 32. Therefore, as described above, digital amount of frame data (pixel data) reflecting the amount of X-ray transmission is output from the detector 32 at a rate of 300 fps, for example. This frame data is temporarily stored in the buffer memory 53.
- the processing instruction is passed to the image processor 56.
- the image processor 56 reconstructs the reference panoramic image PIst based on shift & add based on the tomosynthesis method corresponding to the spatial position of the 3D reference tomographic plane SS, and stores each pixel value of the reconstructed image (step S2). ).
- this reconstruction process a process of multiplying the coefficients so that the ratio of the vertical and horizontal enlargement ratios is the same at the center of the front teeth is performed as in the conventional case.
- the set of frame data used for this reconstruction is, for example, mapping characteristics indicating the relationship between the horizontal mapping position of the panoramic image shown in FIG. 7 and the set of frame data to be mutually added to create an image of the mapping position. It is requested from.
- the curve indicating the mapping characteristics includes both a curved portion having a steep slope according to the molar portion on both sides in the frame data direction (horizontal axis) and a curved portion having a gentler slope than that of the molar portion according to the front tooth portion. Consists of.
- a desired mapping position in the horizontal direction of the panoramic image is designated as shown in the figure.
- a set of frame data used for creating an image at the mapping position and its shift amount (the degree of superposition: that is, the inclination) are obtained. Therefore, these frame data (pixel values) are added to each other while being shifted by the designated shift amount, and vertical image data of the designated mapping position (range) is obtained.
- the reference panorama image PIst when focused on the 3D reference tomographic plane SS is reconstructed by specifying the mapping position and shifting & adding the entire panoramic image in the horizontal direction.
- the image processor 56 displays the reference panoramic image PIst on the monitor 60 (step S3).
- An example of the reference panoramic image PIst is schematically shown in FIG.
- the reference panoramic image PIst is a rectangular two-dimensional image because it is an image obtained by adding frame data to each other while shifting.
- the vertical and horizontal image distortion due to the enlargement ratio is the same as in the past. It has been improved to some extent.
- the aspect ratio of the teeth collapses as it proceeds to the molar part. That is, the teeth of the molar portion are drawn with a size smaller than the actual size. In the past, in many cases, panoramic images with such distortion were put up.
- the image processor 56 determines whether or not an ROI (region of interest) is set in the reference panoramic image PIst by using the operation device 58 from the operator (step S4).
- the ROI set here is, for example, a rectangular partial region in which the image interpreter is particularly interested. Of course, the ROI is not necessarily rectangular. This ROI may be set for a panoramic image created by autofocus described later, and this processing will also be described later.
- step S4 determines whether the determination in step S4 is YES. If the determination in step S4 is YES, the image processor 56 sets the ROI to the reference panoramic image PIst based on the operation information of the operator (step S5). Next, a partial image of the partial area set by the ROI is cut out, and the partial image is enlarged and displayed, for example (step S6). For example, as shown in FIG. 9, this partial image is displayed so as to be superimposed on the original reference panoramic image PIst. Further, the one or more partial images may be displayed so as to fit in a so-called template in which blocks are arranged in a predetermined order so as to schematically represent the upper teeth and lower teeth.
- the image processor 56 determines whether or not to end the processing. This determination depends on whether or not there is predetermined operation information from the operator (step S7). If it is determined that the process is not yet finished (NO in step S7), the process returns to step S4 and the above-described process is repeated. On the other hand, if it is determined that the process has been completed, the process shown in FIG. 5 is terminated.
- step S4 determines whether or not the ROI is not set. If the determination in step S4 is NO, that is, if it is determined that the ROI is not set, the image processor 56 proceeds to the next determination. That is, it is determined from the operation information of the operator whether or not to create a 3D autofocus image as the main process (step S8). When it is determined that this creation is not performed (step S8, NO), the process returns to step S7 to determine whether or not the process is ended as described above.
- step S9 a subroutine process in step S9.
- the process executed in step S9 is one of the features of the present invention, and is performed automatically while correcting distortion of the dentition size caused by the oblique X-ray irradiation direction in the Z-axis direction. This is identification processing of the existing position and shape of the dentition.
- FIG. 10 shows a subroutine process for identifying the actual position / shape.
- the image processor 56 creates an image of the 3D reference tomographic plane SS in consideration of the X-ray irradiation direction (step S51). Specifically, the reference panorama image PIst (rectangular) is coordinate-transformed into a curved surface parallel to the 3D reference tomographic plane SS (curved surface) to create a 3D panoramic image. Then, each of the pixels of the 3D panoramic image is projected onto the 3D reference tomographic plane SS along the X-ray irradiation direction DRx by calculating the tomographic plane, calculating the frame data, and projecting the coordinate data by converting the frame data. A projection image of the reference tomographic plane SS is created. The pixel value of this projection image is stored in the image memory 54.
- the projection performed here is performed along an oblique projection direction toward the position of the rotation center RC (RC1, RC2), that is, the position of the X-ray tube 31, as described in FIG.
- RC1, RC2 the position of the X-ray tube 31
- the difference in the position of the X-ray tube 31 causes the image on the 3D reference tomographic plane SS to be displayed. Projected to different positions SS1, SS2.
- the projection image created by this projection processing will be referred to as 3D reference image PIref.
- the 3D reference image PIref is created by oblique projection in consideration of the above-described enlargement ratio for each position of the reference panoramic image PIst.
- the enlargement rate of the teeth of the anterior teeth was corrected to the actual size by the above projection, while the enlargement rate of the teeth of the molar portion was small, Corrected to actual size rather than projection. Therefore, the 3D reference image PIref is an image displayed at the actual size of the tooth, and is an image from which distortion due to the magnitude of the enlargement ratio due to the movement of the rotation center RC during scanning is removed.
- the 3D reference image PIref is also an image when it is assumed that the dentition exists along the 3D reference tomographic plane SS. Since the actual tooth of the subject P is rarely along the 3D reference tomographic plane SS, further real position identification processing described later is required.
- the image processor 56 displays the 3D standard image PIref on the monitor 60 for reference by the operator (step S52). This is shown in FIG.
- the image processor 56 adds a plurality of curved tomographic planes parallel to the 3D reference tomographic plane SS (step S53). This is shown in FIG. In the drawing, a plurality of tomographic planes are added before and after the X-ray irradiation direction DRx (dentation depth direction) of the 3D reference tomographic plane SS.
- a plurality of tomographic planes SFm to SF1 are set at a distance D1 (for example, 0.5 mm) on the front side of the 3D reference tomographic plane SS, and a plurality of tomographic planes SR1 to SRn are spaced at a distance D2 (for example, 0.5 mm) on the rear side.
- the intervals D1 and D2 may be the same or different from each other.
- the position data of the tomographic planes SFm to SF1 and SR1 to SRn to be virtually added is stored in advance in the ROM 61 together with the position data of the 3D reference tomographic plane SS, and is read out to the work area of the image processor 56. Thus, such addition is performed.
- the heights of the tomographic planes SFm to SF1, SS, SR1 to SRn are appropriately set in consideration of the maximum inclination in the X-ray irradiation direction DRx and the height of the dentition.
- the position (distance D1, D2) and the number of tomographic planes to be added may be interactively changed.
- the image processor 56 considers the angle of the X-ray irradiation direction DRx, and changes the tomographic plane to each of the added tomographic planes SFm to SF1, SR1 to SRn in consideration of the angle of the X-ray irradiation direction DRx, as in step S51.
- the frame data is obtained by the above calculation, and is projected by converting the coordinates (step S54).
- projection images of the additional tomographic planes SFm to SF1, SR1 to SRn are created.
- the pixel values of these projected images are stored in the image memory 54.
- the projection images created here are called 3D additional images PIsfms, PIsf1, PIsr1,..., PIsrn.
- These 3D additional images PIsfm,..., PIsf1, PIsr1,..., ⁇ ⁇ ⁇ ⁇ PIsrn are also created for each position of the reference panoramic image PIst by oblique projection in consideration of the above-described enlargement ratio.
- the 3D additional image PIsfm Projected at different positions on each of PIsf1, PIsr1, ..., PIsrn.
- these 3D additional images PIsfm, ..., PIsf1, PIsr1, ..., PIsrn are also images displayed at the actual size of the teeth, and distortion due to the magnitude of the magnification due to movement of the rotation center RC during scanning is removed. It is an image that was made.
- these 3D additional images PIsfm,..., PIsf1, PIsr1,..., PIsrn are also images when it is assumed that the dentitions exist along the respective additional tomographic planes SFm to SF1 and SR1 to SRn.
- a line segment Lc having a fixed length with the specified position P (x, y, z) as the center is specified in the 3D reference image PIref (see step S56: FIG. 15B).
- the line segment Lc may be curved along a part of the curved 3D reference tomographic plane SS, or may be set within a range that can be regarded as a straight line.
- the image processor 56 virtually adds a plurality of line segments Ladd having the same length above and below the image of the specified line segment Lc (x, y, z) (step S57: FIG. 15C )reference).
- the pixel values P ij of the 2 n pixels constituting each of the line segment L and the plurality of line segments Ladd described above are read from the image memory 54 and assigned to each line segment (step S58).
- This pixel value P ij is a value that has already been acquired and stored in steps S51 and S54 described above.
- Step S59 see FIG. 15D.
- the image processor 56 adds the line segment Lc (x, y, z) currently specified on the above-mentioned 3D reference image PIref in each of the added 3D additional images PIsf1, ..., PIsf1, PIsr1, ..., PIsrn. Identifies the positions of the opposing line segments Lfm to Lf1 and Lr1 to Lrn in the X-ray irradiation direction DRx passing through the currently designated position P (x, y, z) (step S60: see FIG. 15E). ).
- step S60 for specifying the position P (x, y, z) on the 3D reference image PIref is repeated until all the positions are specified. Therefore, in effect, the X-rays irradiated from the X-ray tube 31 whose position is near the virtual tomographic planes SFm to SF1, SS, SR1 to SRn are in the range H1 to H2 (range in the Z-axis direction). It is transmitted in a fan shape (FIG. 15F). For this reason, the tomographic planes SFm to SF1, SS, SR1 to SRn themselves may be set as substantially horseshoe-shaped cross sections whose height changes for each scanning direction and is parallel to each other.
- the image processor 56 reads out the pixel values P ij * of these line segments from the image memory 54 (step S61).
- the X-ray irradiation range RA has a fan shape (when viewed from the Z-axis direction). For this reason, the number of pixels of each of the line segments Lfm to Lf1 and Lr1 to Lrn is deviated from 2n .
- the image processor 56 the additional line segments Lfm ⁇ Lf1, Lr1 ⁇ number of pixels as a reference of Lrn line Lc (x, y, z) to be the same as the number of pixels the 2 n, the line segment Each of Lfm to Lf1 and Lr1 to Lrn is multiplied by a coefficient corresponding to the intervals D1 and D2 (step S62). Accordingly, as schematically shown in FIG. 15G, all the line segments Lfm to Lf1, Lc and Lr1 to Lrn are composed of 2n pixels which are parallel to each other.
- the image processor 56 performs frequency analysis on changes in the values of all the prepared line segments Lf1 to Lfm, Lc, and Lr1 to Lrn (step S63).
- analysis results are obtained with the horizontal axis representing the frequency and the vertical axis representing the Fourier coefficient (amplitude value).
- FFT fast Fourier transform
- an equivalent process may be performed using a Sobel filter that performs a first-order differential operation for rendering an edge. When this filter is used, the position of the tomographic plane having the maximum edge can be regarded as the optimum focus position.
- FIG. 16 illustrates frequency analysis characteristics for one line segment.
- the coefficient of the frequency component in the region of the certain range of the analyzed highest frequency is excluded, and the coefficient of the remaining high frequency component is adopted. This is because the frequency component in a certain range on the highest frequency side is a noise component.
- the cross-sectional position is a position in the X-ray irradiation direction DRx (depth direction of the dentition) of the plurality of tomographic planes SF1 to SFm, SS, FR1 to FRn.
- FIG. 18 illustrates typical patterns of a plurality of types of profiles PR1, PR2, PR3, and PR4 in the case where the material is enamel, cancellous bone, air, and bite block.
- an enamel substance that is, a tooth exists at any position in the X-ray irradiation direction DRx passing through the currently designated position P (x, y, z)
- the profile PR1 has a sharp peak.
- the profile PR2 is a gentle convex curve.
- the profile PR3 is a curve showing a tendency not to have a specific peak.
- the profile PR4 has two sharp peaks.
- the peak corresponding to the inner side (X-ray tube side) of the X-ray irradiation direction DRx indicates the peak for the enamel substance
- the peak corresponding to the outer side (detector side) indicates the peak for the bite block.
- Data indicating the patterns PR1 to PR4 shown in FIG. 18 is stored in advance as a reference profile, for example, in the ROM 61 as a reference table.
- the image processor 56 specifies the position of the optimum focus with respect to the tooth in the X-ray irradiation direction DRx passing through the currently designated position P (x, y, z) using the reference table (step S66). .
- the pattern recognition technique determines by the pattern recognition technique which of the reference profiles PR1 to PR4 corresponds to the profile obtained in the previous step S65.
- the obtained profiles are the reference profiles PR2 and PR4, they are excluded from processing.
- the obtained profile corresponds to the reference profile PR1 (enamel)
- the cross-sectional position exhibiting the peak that is, any one of the plurality of tomographic planes SF1 to SFm, SS, FR1 to FRn is the optimum focus. Identify as being.
- a cross-sectional position (enamel position) having a peak on the inner side (X-ray tube side), that is, a plurality of tomographic planes SFm to SF1, SS, FR1 to Any position of FRn is specified as the optimum focus.
- These position specifying processes determine which position in the depth direction the portion of the tooth at the currently designated position P (x, y, z) is actually located. That is, the tooth portion depicted in the 3D reference image PIref along the 3D reference tomographic plane SS may actually be on the front side or the rear side of the tomographic plane SS. This actual position is accurately determined by the above-described specifying process. In other words, it can be said that the tooth portion of the 3D reference image PIref drawn on the assumption that it is on the 3D reference tomographic plane SS is shifted to the actual position by the above-described specific processing.
- the position P1 in the 3D reference tomographic plane SS (3D reference image PIref) is P1real (or P2 is P2real).
- the positions of line segments Lfm to Lf1 and Lr1 to Lrn set on the plurality of additional tomographic planes SFm to SF1, FR1 to FRn are set in consideration of the oblique angle ⁇ in the X-ray irradiation direction DRx. For this reason, the shifted position P1real is larger when the oblique angle ⁇ is smaller (see FIGS. 20A and 21A) (see FIGS. 20B and 21B).
- the shift position P1real is compensated for the distortion due to the oblique X-ray irradiation angle ⁇ , that is, the magnification ratio.
- ⁇ the magnification ratio
- step S65 the image processor 56 stores the identified data indicating the actual tooth position in the work area for each position P (x, y, z).
- the position P (x, y, z) currently specified in the 3D reference image PIref that is, the 3D reference tomographic plane SS
- the focus position is identified.
- the image processor 56 determines whether or not the above-described specific processing has been completed for all the determination positions P set in advance on the 3D reference image PIref as shown in FIG. 23, for example (step S67). This determination is made by determining whether or not the currently processed position P (x, y, z) is the final position P (p, q, r). If this determination is NO and the specific processing has not been completed for all the determination positions P, the image processor 56 shifts the determination position P (x, y, z) by one (step S68). The process returns to step S55 described above, and the above-described series of specific processes is repeated.
- the plurality of determination positions P are preliminarily arranged two-dimensionally at a predetermined interval along the 3D reference image PIref (that is, the 3D reference tomographic plane SS).
- the 3D reference image PIref is arranged along the vertical axis direction i and the horizontal axis direction j with the same predetermined distance d in the vertical and horizontal directions.
- the predetermined distance d may be different from each other in the vertical axis direction i and the horizontal axis direction j.
- the shift direction in the process of step S68 may be any of vertical, horizontal, and diagonal directions along the 3D reference image PIref. As shown in FIG.
- shifting in the horizontal axis direction j and shifting along the vertical axis direction i may be repeated regularly ( (See symbol SC in the figure). Conversely, shifting in the horizontal axis direction j and then shifting in the vertical axis direction i may be repeated. Further, it may be shifted in an oblique direction.
- step S67 described above becomes YES in the above-described repeated determination. That is, the process of detecting the cross-sectional position of the optimal focus (including the determination of the presence or absence of the optimal focus position) is completed for each determination position P in the depth direction of the 3D reference tomographic plane SS. In this case, the process shifts to the process of combining the cross-sectional positions of the optimum focus.
- step S67 the image processor 56 reads data representing the cross-sectional position of the optimum focus specified and stored in step S65 (step S68).
- the data of the cross-sectional position is a position in the X-ray irradiation direction DRx that passes through each determination position P (x, y, z).
- black circles indicate the determination position P (x, y, z) of the 3D reference image PIref (3D reference tomographic plane SS).
- the vertical direction and the horizontal direction of the curved 3D reference image PIref are represented as (i, j).
- the image processor 56 removes noise (step S70).
- the image processor 56 determines that the difference between the cross-sectional positions is noise and abnormal by, for example, threshold determination.
- the data of the positions of adjacent cross sections are smoothed so as to be smoothly connected, and replaced with the smoothed new position data, or data close to the outside of the detector is given priority, etc. Perform the process.
- the abnormal data may be simply excluded from the processing target without performing such compensation by replacement. Naturally, it is also possible to add an abnormality of data in the Z-axis direction to the exclusion of the abnormal data.
- the image processor 56 combines the denoised positions (namely, enamel positions) and smoothes the data of the combined positions three-dimensionally to create a surface image in which the enamel is traced (step). S71). Further, the image processor 56 causes the monitor 60 to display a 3D panoramic image in which all the parts are automatically subjected to the optimum focus processing on the monitor 60 as a 3D autofocus image PIfocus at a predetermined view angle (see FIG. Step S72).
- a 3D autofocus image PIfocus that can be formed along the contour where the structure of the dentition of the oral cavity of the subject P can be seen most clearly when viewed at a desired view angle.
- a curved horseshoe-shaped range S is a range for displaying a 3D autofocus image PIfocus
- a solid line portion represents an actual position and shape of the dentition.
- the gums (alveolar bone) part mandibular sinus, temporomandibular joint, carotid artery, etc.
- the 3D autofocus image PIfocus is curved along the dentition, but its surface is bumpy, and this “bumpy” gives the actual position and shape (contour) of each tooth to the pixel It is expressed by shading.
- Other parts can also be expressed as images with no sense of incongruity.
- the image processor 56 gives the operator an opportunity to observe the 3D autofocus image PIfocus in another manner. That is, the image processor 56 determines whether or not to interactively display the 3D autofocus image PIfocus in another manner based on operation information from the operator.
- the image processor 56 determines whether or not to observe a partial region of the 3D autofocus image (3D panoramic image) PIfocus (FIG. 5, step S10). If the determination in step S10 is YES, the observation of the partial area is further performed on the 3D reference tomographic plane SS or on the rectangular plane (two-dimensional) of the reference panoramic image, based on information from the operator. (Step S11). If it is determined in step S11 that the 3D reference tomographic plane SS is to be used, the image processor 56 re-projects the 3D autofocus image PIfocus onto the 3D reference tomographic plane SS along the X-ray irradiation direction DRx passing through each pixel. (Step S12).
- This re-projection is executed by a sub-pixel method in which one pixel of a 3D reference tomographic plane is separated from a corresponding three-dimensional pixel by a sub-pixel and re-projected.
- the reprojected image on the 3D standard tomographic plane SS is displayed on the monitor 60 as a 3D reference image PI proj-3D (step S13).
- An example of the 3D reference image PI proj-3D is shown in FIG.
- step S11 when it is determined in step S11 that the rectangular plane of the reference panoramic image PIst is used, the image processor 56 re-projects the 3D autofocus image PIfocus onto the rectangular plane, that is, the plane of the reference panoramic image (step S14).
- This reprojection is also performed by a so-called conventionally known subpixel method in which one pixel of a standard panoramic image plane is reprojected by dividing a corresponding three-dimensional pixel by a subpixel. The concept of this reprojection is shown in FIG.
- This reprojection image is displayed on the monitor 60 as a 2D reference image PI proj-2D (step S15).
- An example of the 2D reference image PI proj-2D is shown in FIG.
- the operator sets a desired, for example, rectangular ROI (region of interest) in this 3D reference image PI proj-3D or 2D reference image PI proj-2D (step S16: see FIGS. 27 and 29).
- the image of the partial area specified by this ROI is enlarged, for example, and is superimposed and displayed on, for example, the currently displayed 3D reference image PI proj-3D or 2D reference image PI proj-2D (step S17).
- this display may be a single image separate from the panoramic image, may be a divided display with the panoramic image, or may be one of templates composed of a plurality of blocks simulating a dentition.
- the stored display may be used.
- the image processor 64 determines whether or not to end the series of processes from the operation information (step S18). If this determination is YES, the process returns to step S7 described above. On the other hand, if NO, the process returns to step S10 and the above-described process is repeated.
- step S10 when it is determined in step S10 described above that the partial image is not observed, the image processor 56 displays the currently displayed 3D autofocus image PIfocus by rotating, moving, and / or enlarging / reducing it. Whether or not interactively is determined (step S19). If this determination is YES, the 3D autofocus image PIfocus is rotated, moved, and / or enlarged / reduced according to the command information, and the image is displayed (steps S20 and S21). Thereafter, the process is passed to step S81, and the same process as described above is repeated.
- display modes are not limited to those described above, and various other modes such as colorization can be adopted.
- the image processor 64 ends the process through steps S18 and S7.
- step S16 you may make it transfer to the process of step S19, without performing the display process of step S17.
- the set ROI is displayed in step S21 together with the rotated, moved, enlarged / reduced image.
- an image focused on at least the entire region of the dentition is provided as a 3D autofocus image PIfocus (three-dimensional panoramic image).
- a 3D autofocus image PIfocus three-dimensional panoramic image
- the optimum focusing process is automatically executed only by the operator issuing a command to that effect, and the 3D autofocus image PIfocus is displayed. That is, the autofocus function is exhibited.
- there are many image observation variations such as rotating the 3D autofocus image PIfocus and displaying the 3D autofocus image PIfocus while enlarging and displaying the region by the ROI.
- the panoramic imaging apparatus of the present embodiment is also suitable for screening.
- the change in the magnification according to the change in the rotation position during the scan that is, the position of the rotation center RC of the pair of the X-ray tube 31 and the detector 32 is also compensated in the process of creating the 3D autofocus image PIfocus. Yes. For this reason, the distortion resulting from the change in the enlargement ratio is corrected, and an image that accurately reflects the actual size and the actual shape can be provided.
- the displayed image has some degree of distortion, but the positional relationship with the 3D autofocus image is small. Correspondence is taken. For this reason, distances, such as the length of the longitudinal direction of a tooth, can be measured correctly, for example.
- the positions of the X-ray tube 31 and the detector 32 at the time of data collection (scanning) are grasped in advance three-dimensionally with respect to the dentition. There is no need to measure the tomographic distance information in advance using a phantom as in the prior art. Therefore, the operability is good for the operator and the processing load on the image processor 56 is reduced accordingly.
- the clip 70 shown in the figure has small pieces 71 as two quadrangular landmarks, and these two small pieces 71 are connected to each other alternately by wire rods 72 with a spring mechanism.
- the small piece 71 is formed of an appropriate material higher than the X-ray absorption rate of the oral cavity, and functions as a landmark for X-rays.
- FIGS. 30B and 30C show a state where the clip 70 is installed on a part of the dentition of the subject.
- the two small pieces 71 are fixed and arranged by the wire rod 72 with the gums sandwiched between the front and rear of the teeth (dentition), that is, in different directions in the direction along the teeth.
- the three-dimensional positions of the two small pieces 71 are grasped through the above-described autofocus process of FIG. 10, and the cross-sections CR1 and CR2 including the three-dimensional positions of the small pieces 71 ( Two images with optimum focus on (see FIG. 30C) are created. As shown in FIG.
- the frequency characteristic pattern employed in this image creation is two profiles RR5 in which the peak of the frequency characteristic of the small piece 71 appears on both sides of the frequency characteristic PR2 of the cancellous bone.
- the image processor 56 refers to the two profiles RR5 separately and performs a reconstruction process similar to that in the above-described embodiment.
- the two pieces 71 each of the three-dimensional position P 1 real: and (P 1'real FIG see 20-22), comprising those two best focus image (partial image of a cross section CR1, CR2 containing each different Is good).
- the image processor 56 can calculate the thickness of the alveolar bone flanked by two pieces 71. This is effective not only for diagnosis of the alveolar bone but also for determining where in the thickness direction the cross section of the alveolar bone to be observed is set.
- FIG. 33 Another landmark is shown in FIG. This landmark is a mesh-like stretchable mask 80 that is in close contact with the surface of the subject's face. Since the X-ray absorption rate of each wire forming the mask 80 is different from that of the oral cavity, it is equivalent to drawing a lattice-like line on the face surface with an X-ray marker by bringing the mask 80 into close contact with the face. is there. These lines may simply be parallel lines.
- an X-ray absorber such as Value may be applied on the face surface in a line or in a lattice pattern.
- a grid-like line 81 shown in FIG. 33 is a landmark for X-rays.
- a granular X-ray absorber may be mixed with a quick-drying cosmetic agent, and this cosmetic agent may be applied to the face.
- a granular X-ray absorber can be placed on the face surface as a landmark.
- the profile of the frequency characteristic is as shown by a graph PR6 in FIG.
- the image processor 56 employs the profile PR6 to perform the above-described autofocus reconstruction processing.
- an optimally focused image of the surface along the three-dimensional position that is, an X-ray transmission image of the face surface is obtained along with the three-dimensional position of each landmark.
- a substitute image for cephalometry can be provided.
- a pair of an X-ray tube and a detector may be installed on the ceiling.
- the entire device can be downsized and operated (mobile structure) so that it can be mounted on a medical examination car or taken in at home.
- the detector that can be employed in the radiation imaging apparatus according to the present invention is not limited to the above-described digital detector using CdTe, but may be a known photon counting type detector.
- this photon counting type detector for example, one disclosed in Japanese Patent Application Laid-Open No. 2004-325183 is known.
- the detectors used in the radiation imaging apparatus according to the present invention need not always be the same type. Since it is necessary to change the energy of X-rays to be generated according to the type of imaging target, the material of the X-ray detection element may be selected so as to have an X-ray absorption coefficient accordingly. When the X-ray generation energy is large, a detector having an X-ray detection element made of LaBr 3 , CdTe, CZT, GOS or the like may be selected. If the generated energy of X-rays is small, a detector including an X-ray detection element made of Si, CdTe, CZT, CsI, or the like may be selected.
- the present invention is not limited to a mode for displaying a three-dimensional panoramic image (surface image).
- a mode for displaying a three-dimensional panoramic image surface image
- the width that seems to be focused is obtained from the tomographic plane and the frequency characteristic graph, and the thickness of each tooth and alveolar bone is calculated.
- the estimation that is, the thickness in the depth direction may be measured. If the configuration for obtaining this measurement information is implemented in the vicinity of the alveolar bone near the first premolar, for example, in combination with the above-described photon counting type detector, the bone mineral content can be quantitatively measured.
- the imaging according to the present invention is also performed near the lower sinus of the oral cavity, image information relating to the three-dimensional structure of the lower sinus can be provided to some extent. By observing the left-right difference on this image, it is possible to detect a lesion such as mandibular sinusitis (pyremic syndrome) with higher accuracy than before.
- imaging according to the present invention is performed focusing on the vicinity of the carotid artery, the calcification of the carotid artery, which is said to contribute to arteriosclerosis, can be clearly displayed in three dimensions, and diagnostic information with higher accuracy than before can be obtained. Can be provided.
- the radiation imaging apparatus according to the present invention is not limited to the one implemented in the dental panoramic imaging apparatus, but widely used for grasping the three-dimensional shape (position) inside the object using the tomosynthesis method. Can be implemented. Such applications include, for example, medical applications such as mammography using the tomosynthesis method and lung cancer scanners.
- the radiation imaging apparatus according to the present invention can be applied to a nuclear medicine diagnostic apparatus called emission CT (ECT) such as a gamma camera or SPECT.
- ECT nuclear medicine diagnostic apparatus
- RI radioisotope
- the RI and collimator constitute a radiation emission source.
- the number of detectors in the radiation imaging apparatus according to the present invention is not necessarily limited to one, and can be applied to a modality in which two or more detectors are operated simultaneously or in parallel.
- the radiation imaging apparatus is used for industrial purposes, the contents of products and products conveyed by a belt conveyor and acquisition of position information thereof, and the tertiary wiring structure of a flexible substrate connected to a flat panel display.
- applications such as acquisition of three-dimensional distribution and size information of casting molds, acquisition of position information of contents of baggage inspection at airports.
- the object can be moved along various directions such as a straight line, a circle, and a curved surface. That is, the 3D reference tomographic plane may also be a tomographic plane having a planar shape, a cylindrical shape, or a curved shape.
- the object to be imaged may be moved relative to the pair of the X-ray tube and the detector depending on circumstances.
- only the detector may be moved relative to the imaging object or subject and the radiation source.
- the entire area of the image is optimally focused in a state where the actual state (position, shape) of the imaging target is rendered three-dimensionally with high accuracy, and almost no distortion of the image due to the difference in magnification is eliminated. Therefore, it is possible to provide a radiation imaging method that can provide a three-dimensional panoramic image, and the industrial applicability is extremely large.
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Abstract
Description
続いて、図5を用いて、コントローラ57及び画像プロセッサ56により協働して実行される処理を説明する。この処理には、上述したように、スキャンによりデータ収集、プレ処理としての基準パノラマ画像の再構成、並びに、メインの処理としての3次元オートフォーカス画像(表面画像)の作成及びその3次元オートフォーカス画像を用いた各種態様に応じた表示や計測などが含まれる。
まず、コントローラ57は、被検体Pの位置決めなど撮影の準備が済むと、コントローラ57は、3D基準断層面SSの位置情報をROM61から読み出す(ステップS0)。この3D基準断層面SSは前述したように、統計的に定めた断面であってもよいし、被検者各人から予め設定しておいた断面であってもよい。
次いで、画像プロセッサ56は操作者から操作器58を使って基準パノラマ画像PIstにROI(関心領域)が設定するか否かを判断する(ステップS4)。ここで設定するROIは、読影者が特に関心を寄せる例えば矩形状の部分領域である。勿論、ROIは必ずしも矩形でなくてもよい。なお、このROIは、後述するオートフォーカスにより作成したパノラマ画像について設定してもよく、この処理も後述される。
これに対して、3Dオートフォーカス画像を作成すると判断した場合(ステップS8、YES)、ステップS9のサブルーチン処理に移行する。このステップS9で実行される処理は、本発明の特徴の一つを成すもので、Z軸方向にオブリークなX線照射方向に起因した歯列のサイズの歪みを補正しながら行なう、自動的な歯列の実存位置・形状の同定処理である。
上述したステップS67の判断がYESとなると、画像プロセッサ56はステップS65において特定し記憶していた最適焦点の断面位置を表すデータを読み出す(ステップS68)。この断面位置のデータは、それぞれの判断位置P(x、y、z)を通るX線照射方向DRxの位置である。この様子を図24に模式的に示す。同図において、黒丸は3D基準画像PIref(3D基準断層面SS)の判断位置P(x、y、z)を示す。ここで、湾曲した3D基準画像PIrefの縦方向及び横方向を(i, j)と表す。図24において、白丸で示す如く、例えば、i,j=0,0の判断位置P(x00、y00、z00)に対する最適焦点断面位置が内側(X線管の側)に1つ寄った断層面SR1の位置であり、その隣のi,j=0,1の判断位置P(x01、y01、z01)に対する最適焦点断面位置が内側さらに1つ寄った断層面SR2の位置であり、その隣のi,j=0,2の判断位置P(x02、y02、z02)に対する最適焦点断面位置が内側さらに1つ寄った断層面SR3の位置であり、といった具合になる。なお、図24は、図を見易くするため、Z軸方向(縦方向)の1つの位置におけるステップS68を示しているが、このZ軸方向の他の位置それぞれについてもステップS68の処理が実行される。
この後、画像プロセッサ56は、その3Dオートフォーカス画像PIfocusを他の態様で観察する機会を操作者に与える。つまり、画像プロセッサ56は、操作者から操作情報に基づいて、その3Dオートフォーカス画像PIfocusを他の態様でインターラクティブに表示するか否かを判断する。
本実施例に係るパノラマ撮像装置によれば、以下のような顕著な作用効果を奏する。
上述した実施形態では、被検者の口腔部の歯列の最適焦点化した3次元画像を得る例を説明したが、これを更に展開することができる。一例として、口腔部に、適宜なX線吸収率を有する放射線吸収材で成るランドマーク(マーカ)を設置し、この設置状態で前述した実施形態と同様にデータを収集し、そのランドマークの位置を認識するとともに、そのランドマークを含む面に焦点を合わせた画像を作成することである。
12 コンピュータ
14 撮影部
31 X線管(放射線管)
32 検出器
33 コリメータ
41 高電圧発生器
53 バッファメモリ
54 画像メモリ
55 フレームメモリ
56 画像プロセッサ
57 コントローラ
58 操作器
60 モニタ
61 ROM
Claims (21)
- 放射線を放出する放射線放出源と、
前記放射線が入射したときに当該放射線に対応したデジタル電気量の2次元データをフレーム単位で出力する放射線検出器と、
前記放射線放出源と前記放射線検出器の対、当該放射線検出器、又は、撮像したい対象物を、当該放射線放出源、当該放射線検出器、及び当該対象物の中の残りの要素に対して移動させる移動手段と、
前記移動手段により前記放射線放出源と前記放射線検出器の対、当該放射線検出器、又は、前記対象物を前記残りの要素に対して相対的に移動させている間に、前記放射線検出器から出力される前記データをフレーム単位で収集するデータ収集手段と、
前記データ収集手段により収集された前記データを用いて前記対象物の撮像部位の焦点を最適化し、かつ、当該撮像部位の実際の大きさ及び形状を反映させた3次元最適焦点画像として作成する画像作成手段と、を備えたことを特徴とする放射線撮像装置。 - 前記放射線放出源は、前記放射線を照射する放射線源を有し、
前記放射線源と前記放射線検出器とを前記対象物を挟んで互いに対峙するように配置し、
前記移動手段は、前記放射線源と前記放射線検出器の対を前記対象物の所望の基準断層面に前記放射線によるスキャンの焦点が合うように移動させる手段であり、
前記データ収集手段は、前記移動手段により前記放射線源と前記放射線検出器の対を移動させながら、当該移動中に前記放射線検出器から出力される前記データをフレーム単位で収集する手段であり、
前記画像作成手段は、
前記データ収集手段により収集された前記データを用いて前記基準断層面を前記検出器の検出面に投影させた投影画像を基準面画像として再構成する基準面画像再構成手段と、
前記基準面画像のデータと前記フレームデータとを用いて前記3次元最適焦点画像を作成する最適焦点画像作成手段と、を備えたことを特徴とする請求項1に記載の放射線撮像装置。 - 前記基準断層面の一部又は全体が、カメラにより撮影された表面画像から作成された前記対象物の所望の3次元断面、MRI(磁気共鳴イメージング)装置、CT(コンピュータトモグラフィ)スキャナ、又は超音波診断装置を含む医用モダリティにより撮影された前記対象物の所望の3次元断面、又は、当該医用モダリティにより撮像された当該対象物の3次元データから決めた当該対象物の所望の3次元断面の何れかであることを特徴とする請求項1又は2に記載の放射線撮像装置。
- 前記対象物は被検者の口腔部であり、
前記口腔部に放射線吸収材でなるランドマークを設置した状態で前記移動手段を駆動させて前記データ収集手段で前記データを収集させる構成であり、
前記最適焦点画像作成手段は、前記ランドマークの3次元的な位置を認識するとともに当該ランドマークにより認識される3次元的な位置に焦点を合わせた画像を作成する手段であることを特徴とした請求項1又は2に記載の放射線撮像装置。 - 前記放射線源は、前記放射線としてのX線を発生するX線管であり、
前記放射線検出器は、前記X線を検出する検出器であり、
前記基準断層面は、前記実空間において湾曲した矩形状の3次元(3D)基準断層面であり、
前記対象物の撮像部位は、被検体の歯列であり、
前記基準面画像再構成手段は、前記歯列のパノラマ画像を再構成する手段である、ことを特徴とする請求項2に記載の放射線撮像装置。 - 前記最適焦点画像作成手段は、
前記3D基準断層面に沿う複数の断層面を、当該3D基準断層面に対向した方向に設定する断層面設定手段と、
前記複数の断層面のそれぞれの画素値を演算する画素値演算手段と、
前記3D基準断層面と前記画素値演算手段により画素値が与えられた前記複数の断層面との画像データを用いて前記撮像部位の最適焦点化されたサンプル位置を同定する位置同定手段と、
前記位置同定手段により同定されたサンプル位置に、前記X線管から当該各サンプル位置を介して前記検出器を臨む視線上に存在し且つ前記パノラマ画像の対応するサンプル点の画素値に基づく画素を与える画素値付与手段と、
前記画素値付与手段により画素値が付与された前記サンプル位置における前記3D基準断層面及び前記複数の断層面が有する画素値が示す特性をパターン認識することにより前記歯列を決定する歯列決定手段と、
前記歯列決定手段により決定された前記歯列の特異点を除去する特異点除去手段と、を備えたことを特徴とする請求項5に記載の放射線撮像装置。 - 前記特異点除去手段は、前記サンプル点のそれぞれにおける前記周波数特性に基づいて同種の特性を示す物質毎に分類する分類手段と、この分類手段により分類された物質毎に当該各物質を滑らかに繋ぐスムージング手段とを備えた、ことを特徴とする請求項6に記載の放射線撮像装置。
- 前記基準面画像再構成手段により再構成された、前記3D基準断層面の前記パノラマ画像を表示するパノラマ画像表示手段と、
前記パノラマ画像表示手段により表示されたパノラマ画像上で、操作者にROI(関心領域)を設定させるROI設定手段と、
前記ROIを設定された領域の画像を前記パノラマ画像から切り出して表示する部分画像表示手段と、を備えたことを特徴とする請求項5に記載の放射線撮像装置。 - 前記最適焦点画像作成手段により作成された前記最適焦点画像を表示する最適焦点画像表示手段と、
前記最適画像表示手段により表示された最適焦点画像上で、操作者にROI(関心領域)を設定させる場合、前記最適焦点画像を前記湾曲した3D基準断層面に前記視線の方向に沿って投影し、かつ、この投影した画像をパノラマ画像として作成する作成手段と、
前記作成手段により作成されたパノラマ画像上で、操作者にROI(関心領域)を設定させるROI設定手段と、
前記ROIを設定された領域の画像を前記パノラマ画像から切り出して表示する部分画像表示手段と、を備えたことを特徴とする請求項5に記載の放射線撮像装置。 - 前記最適焦点画像作成手段により作成された前記最適焦点画像を表示する最適焦点画像表示手段と、
前記最適画像表示手段により表示された最適焦点画像上で、操作者にROI(関心領域)を設定させる場合、前記最適焦点画像を2次元の断層面に前記視線の方向に沿って投影し、かつ、この投影した画像をパノラマ画像として作成する作成手段と、
前記作成手段により作成されたパノラマ画像上で、操作者にROI(関心領域)を設定させるROI設定手段と、
前記ROIを設定された領域の画像を前記パノラマ画像から切り出して表示する部分画像表示手段と、を備えたことを特徴とする請求項5に記載の放射線撮像装置。 - 前記部分画像表示手段は、前記切出し画像を、歯列を模したテンプレートに収めて表示する手段である、ことを特徴とする請求項9又は10に記載の放射線撮像装置。
- 前記基準面画像再構成手段により再構成されたパノラマ画像及び前記最適焦点画像作成手段により作成された最適焦点画像のうちの少なくとも一方を3次元的に表示する3次元表示手段を備えたことを特徴とする請求項5に記載の放射線撮像装置。
- 前記3次元表示手段は、前記パノラマ画像及び前記最適焦点画像のうちの少なくとも一方を、回転及び移動の少なくとも一方により表示可能に構成されていることを特徴とする請求項12に記載の放射線撮像装置。
- 放射線を放出する放射線放出源と、
前記放射線が入射したときに当該放射線に対応したデジタル電気量の2次元データをフレーム単位で出力する放射線検出器と、
前記放射線放出源と前記放射線検出器の対、当該放射線検出器、又は、撮像したい対象物を、当該放射線放出源、当該放射線検出器、及び当該対象物の中の残りの要素に対して移動させる移動手段と、
前記移動手段により前記放射線放出源と前記放射線検出器の対、当該放射線検出器、又は、前記対象物を前記残りの要素に対して移動させている間に、前記放射線検出器から出力される前記データをフレーム単位で収集するデータ収集手段と、を備えたシステムから出力される前記データを処理するデータ処理装置において、
前記データを入力し格納するデータ格納手段と、
前記データ格納手段により格納されている前記データを用いて前記対象物の撮像部位の焦点を最適化し、かつ、当該撮像部位の実際の大きさ及び形状を反映させた3次元最適焦点画像として作成する画像作成手段と、を備えたことを特徴とするデータ処理装置。 - 前記画像作成手段は、
前記データ格納手段により格納されている前記データを用いて前記対象物の基準断層面を前記検出器の検出面に投影させた投影画像を基準面画像として再構成する基準面画像再構成手段と、
前記基準面画像のデータを用いて前記3次元最適焦点画像を作成する最適焦点画像作成手段と、を備えたことを特徴とする請求項14に記載のデータ処理装置。 - 前記システムは、前記放射線源に前記放射線としてのX線を発生するX線管を用い、前記放射線検出器に前記X線を検出する検出器を用い、前記基準断層面を前記実空間において湾曲した矩形状の3次元(3D)基準断層面とし、前記対象物の撮像部位を被検体の歯列とした歯科用のパノラマ撮像装置であり、
前記最適焦点画像作成手段は、
前記3D基準断層面に沿う複数の断層面を、当該3D基準断層面に対向した方向に設定する断層面設定手段と、
前記複数の断層面のそれぞれの画素値を演算する画素値演算手段と、
前記3D基準断層面と前記画素値演算手段により画素値が与えられた前記複数の断層面との画像データを用いて前記撮像部位の最適焦点化されたサンプル位置を同定する位置同定手段と、
前記位置同定手段により同定されたサンプル位置に、前記X線管から当該各サンプル位置を介して前記検出器を臨む視線上に存在し且つ前記パノラマ画像の対応するサンプル点の画素値に基づく画素を与える画素値付与手段と、
前記画素値付与手段により画素値が付与された前記サンプル位置における前記3D基準断層面及び前記複数の断層面が有する画素値が示す特性をパターン認識することにより前記歯列を決定する歯列決定手段と、
前記歯列決定手段により決定された前記歯列の特異点を除去する特異点除去手段と、を備えたことを特徴とする請求項15に記載のデータ処理装置。 - 前記決定手段により決定された前記撮像部位の特異点を除去する特異点除去手段と、を備えたことを特徴とする請求項16に記載のデータ処理装置。
- 前記特異点除去手段は、前記サンプル点のそれぞれにおける前記周波数特性に基づいて同種の特性を示す物質毎に分類する分類手段と、この分類手段により分類された物質毎に当該各物質を滑らかに繋ぐスムージング手段とを備えた、ことを特徴とする請求項17に記載のデータ処理装置。
- 放射線放出源と、この放射線放出源から放射線が入射したときに当該放射線に対応したデジタル電気量の2次元データをフレーム単位で出力する放射線検出器との対、当該放射線検出器、又は、撮像する対象物を、当該放射線放出源、当該放射線検出器、及び当該対象物の中の残りの要素に対して相対的に移動させながら、当該移動中に前記放射線検出器から出力される前記データをフレーム単位で収集するデータ収集ステップと、
前記データ収集ステップで収集された前記データを用いて前記対象物の撮像部位の焦点を最適化し、かつ、当該撮像部位の実際の大きさ及び形状を反映させた3次元最適焦点画像として作成する画像作成ステップと、を備えたことを特徴とする放射線を用いた撮像方法。 - 前記画像作成ステップは、
前記データ収集ステップにより収集された前記データを用いて前記対象物の撮像部位の所望の基準断層面を前記放射線検出器の検出面に投影させた投影画像を基準面画像として再構成するステップと、
前記基準断層面に沿う複数の断層面を、当該基準断層面に対向した方向に設定するステップと、
前記複数の断層面のそれぞれの画素値を、前記基準断層面の画素値を用いて演算するステップと、
前記基準断層面と前記画素値が与えられた前記複数の断層面との画像データを用いて前記撮像部位の最適焦点化されたサンプル位置を同定するステップと、
前記同定されたサンプル位置に、前記X線管から当該各サンプル位置を介して前記検出器を臨む視線上に存在し且つ前記基準面画像の対応するサンプル点の画素値に基づく画素を与えるステップと、
前記画素値が付与された前記サンプル位置における前記基準断層面及び前記複数の断層面が有する画素値が示す特性をパターン認識することにより前記撮像部位の位置を決定するステップと、
前記決定された撮像部位の位置のうちの特異点を除去するステップと、を含むことを特徴とする請求項19に記載の放射線を用いた撮像方法。 - メモリに予め格納され、かつ、当該メモリから読み出し可能なプログラムであって、放射線を放出する放射線放出源と、前記放射線が入射したときに当該放射線に対応したデジタル電気量の2次元データをフレーム単位で出力する放射線検出器と、前記放射線放出源と前記放射線検出器の対、当該放射線検出器、又は、撮像したい対象物を当該放射線放出源、当該放射線検出器、及び当該対象物の中の残りの要素に対して相対的に移動させる移動手段と、前記移動手段により前記放射線放出源と前記放射線検出器の対、当該放射線検出器、又は、前記対象物を前記残りの要素に対して移動させている間に、前記放射線検出器から出力される前記データをフレーム単位で収集するデータ収集手段と、を備えたシステムから出力される前記データをコンピュータに処理させるプログラムにおいて、
前記コンピュータを、
前記データを用いて前記対象物の撮像部位の所望の基準断層面を前記検出器の検出面に投影させた投影画像を基準面画像として再構成するステップと、
前記基準断層面に沿う複数の断層面を、当該基準断層面に対向した方向に設定するステップと、
前記複数の断層面のそれぞれの画素値を、前記基準断層面の画素値を用いて演算するステップと、
前記基準断層面と前記画素値が与えられた前記複数の断層面との画像データを用いて前記撮像部位の最適焦点化されたサンプル位置を同定するステップと、
前記同定されたサンプル位置に、前記X線管から当該各サンプル位置を介して前記検出器を臨む視線上に存在し且つ前記基準面画像の対応するサンプル点の画素値に基づく画素を与えるステップと、
前記画素値が付与された前記サンプル位置における前記基準断層面及び前記複数の断層面が有する画素値が示す特性をパターン認識することにより前記撮像部位の位置を決定するステップと、
前記決定された撮像部位の位置のうちの特異点を除去するステップと、
前記特異点が除去された前記撮像部位の位置を繋いで当該撮像部位の実際の大きさ及び形状を反映させた3次元最適焦点画像として作成するステップと、機能的に実行させることを特徴とするプログラム。
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CN102469977B (zh) | 2015-04-01 |
US20160015332A1 (en) | 2016-01-21 |
JP2015144898A (ja) | 2015-08-13 |
US9629590B2 (en) | 2017-04-25 |
KR20120059498A (ko) | 2012-06-08 |
EP2465436A4 (en) | 2016-08-17 |
KR101787119B1 (ko) | 2017-11-15 |
JP5731386B2 (ja) | 2015-06-10 |
JP6007386B2 (ja) | 2016-10-12 |
EP2465436A1 (en) | 2012-06-20 |
US9113799B2 (en) | 2015-08-25 |
CN102469977A (zh) | 2012-05-23 |
US20120230467A1 (en) | 2012-09-13 |
JPWO2011013771A1 (ja) | 2013-01-10 |
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