The present invention relates to an X-ray CT apparatus, and particularly to an X-ray CT apparatus which allows selective setting of an X-ray irradiation condition according to a tissue of an object or the like, and allows reduction in exposed dose of the object to the minimum while maintaining an image quality necessary for a diagnosis according to the setting.
The present application is an application associated with claim to priority on the basis of patent application Ser. No. 2005-107566 based upon the Japanese Patent Law, as well as an application which benefits by reference for enjoying a benefit of Patent Application No. 2005-107566.
Techniques for reducing an exposed dose of an object while attempting to improve an image quality have conventionally been developed. For example, in Patent Document 1, a beam hardening error of obtained projection data is subjected to a correction process according to a scanning method, and a plurality of irradiator current values are created, which are then applied to a scanning system according to a scanning subject. It is thereby possible to reduce a dose received by individual objects and also enhance a dose efficiency regardless of sizes of the objects, while holding a low noise level to an allowable extent and favorable CNR.
Patent Document 1: Japanese Patent Laid-Open No. 2004-73865
Image quality of an X-ray CT image is largely involved in visual inspection, by a doctor, of a seat of disease in a tissue of an object or the like. To obtain better image quality, scanning condition can be set in view of absorption or transmission of X-rays specific to and different among each tissue of an object. However, in Patent Document 1, consideration is not given to setting of a scanning condition in view of absorption or transmission of X-rays specific to and different among each tissue of an object.
In an aspect of this disclosure, there is provided an X-ray CT apparatus capable of setting a scanning condition in view of absorption or transmission of X-rays specific to and different among each tissue of an object.
An X-ray CT apparatus, according to an exemplary embodiment of the disclosure, comprises: an X-ray source which irradiates X-rays; an X-ray detector which is arranged oppositely to the X-ray source and detects the irradiated X-rays; a scanner having a rotary disk which rotatably supports the X-ray source and X-ray detector and a power source of the rotary disk; an image processing device which makes the scanner rotate in a state where an object is inserted in between the X-ray source and the X-ray detector to irradiate the object with X-rays from directions at a plurality of angles, and makes the X-ray detector detect X-rays transmitted through the object in directions at a plurality of angles as projection data, to reconstruct a tomographic image of the object by the use of the projection data in the directions at the plurality of angles; a display device which displays the reconstructed tomographic image; a setting device which sets an X-ray irradiation condition candidate by at least one combination of a tube current and a tube voltage for power to be supplied to the X-ray source by the use of a transmission thickness of a scanning subject site of the object; and a control device which supplies the with an X-ray irradiation condition corresponding to the set X-ray irradiation condition candidate, to perform scanning, and in the X-ray CT apparatus, the setting device sets an X-ray irradiation condition candidate by at least one combination of a tube current and tube voltage for power to be supplied to the X-ray source by the use of an X-ray absorption coefficient of the scanning subject site of the object, and the control device makes the display device selectably display each of the set X-ray irradiation condition candidates which is provided for a diagnosis of a requested tissue of the object, to take control such that a tomographic image of the object is taken according to the selected X-ray irradiation condition candidate.
According to the above-mentioned X-ray CT apparatus, it is possible to set a scanning condition in view of absorption or transmission of X-rays specific to and different among each tissue of an object.
In a first embodiment, when a scanning protocol such as a site desired to be diagnosed and the presence or absence of a contrast agent is designated, an image quality index, an exposed dose and the like regarding at least one combination of a tube current and tube voltage which is corresponded to this scanning protocol are calculated and displayed. The user then looks at the displayed results and selects a tube current and a tube voltage to be actually used for scanning.
In the following, embodiments of the present invention are described.
The rotational scanning structure (scanner) 2 has a rotary disk 11 and a scanner driving unit 12 that rotationally drives the rotary disk 11. The scanner driving unit 12 rotates the rotary disk 11 according to a designation from the host computer 1, and at a scanning preparation stage, the scanner driving unit 12 notifies the host computer 1 of completion of preparation at the time when a rotational speed of the rotary disk 11 becomes a predetermined one. The following components are mounted on the rotary disk 11. The X-ray tube 13 is an X-ray source. A high-voltage generator 14 is a power source for generating a voltage and a current for the X-ray tube 13. The detector 15 detects X-rays irradiated from the X-ray tube 13. A transmitter/receiver 17 transmits and receives data to and from a transmitter/receiver 16 provided in a static system (the host computer 1 and the image processing unit 5).
The X-ray tube 13 irradiates X-rays, which is obtained on an X-ray irradiation condition set in a manner as described later, toward the detector 15 during scanning. The detector 15 detects the X-rays having been transmitted through the object, converts the detected X-rays into an electric signal, and then acquires projection data as digital data in a measurement circuit. The projection data is subjected to a variety of processes in the image processing apparatus 5, including a pre-process, a filter process and a back projection process, and reconstructed as a tomographic image. The reconstructed image (tomographic image) is displayed on the display unit 8 to be provided to an image reading person as an image for a diagnosis.
The X-ray irradiation condition setting device 6 is configured as a computer program, and a function of this X-ray irradiation condition setting device 6 is described later.
In controlling of the patient table 3 by the table control portion 4, for example in the case of spiral scanning, the patient table 3 is previously shifted to a position in view of an accelerated time of the patient table 3. Subsequently, the patient table 3 starts shifting from its shifted position, and the table control portion 4 controls the patient table 3 such that the speed of the patient table 3 becomes constant before the patient table 3 reaches a position (X-ray exposure start position) where the object on the patient table 3 starts being irradiated with X-rays.
In the following, a flow of a process in scanning performed by the X-ray CT apparatus of the present embodiment is described. In a scanning mode, first, a scanning protocol is set. Examples of the scanning protocol may include head plain, head CTA (CT Angiography), chest general, chest three-phase scanning, and lower extremity angiography. These scanning protocols are converted into data in a table form as an example shown in
Next, the scanning protocol is shifted to scanogram imaging. The scanogram imaging is aimed at acquiring an image for positioning and information such as a size, namely a transmission thickness, of an object. The scanogram imaging can be performed in the up and down direction and the right and left direction. Although information about a transmission thickness (thickness and width) of an object can normally be obtained by imaging in either the up and down direction or the right and left direction, imaging may be performed in the both directions according to the need.
Subsequently, a scanning condition, a reconstruction condition and the like are set along with setting of a scanning range of a tomographic image by the use of a scanogram. As the scanning conditions, an X-ray irradiation condition, a slice thickness, a table forwarding (spiral pitch) and the like are set.
The X-ray irradiation condition is carried out by the use of the X-ray irradiation condition setting device 6.
Subsequently, an image quality index calculating section 22 calculates an image quality index (Step S102). The image quality index is calculated by the use of an attenuation model. The attenuation model is obtained by modeling a tissue configuration in an image quality index calculating position, namely an attenuation structure of X-rays, as a simplified example shown in
The image quality index calculating section 22 reads an attenuation model corresponding to the scanning protocol set as described above at the start of the image quality index calculation process. The image quality index calculating section 22 then applies the X-ray irradiation condition to this attenuation model and transmission thickness information of the object obtained by the above scanogram analysis, to calculate an image quality index. Here, the image quality index is an index regarding an image quality (image readability) of an image obtained by scanning. SNR (signal/noise ratio), CNR (contrast/noise ratio) or the like can be used for such an image quality index. As described above, contrast of a diagnosis object tissue with a background makes up a large portion of the image readability of an image by the X-ray CT apparatus. Namely, the X-ray CT apparatus has a characteristic that image reading of a diagnosis object tissue is possible when the contrast is large enough with respect to the image noise. By taking advantage of such a characteristic, it is possible to set a further appropriate X-ray irradiation condition. From this perspective, it is more preferable to use CNR for an image quality index, and CNR is used in the present embodiment.
The image quality index is obtained for each of a plurality of X-ray irradiation condition candidates. The X-ray irradiation condition candidates are previously registered in the X-ray irradiation condition database set in the external storage unit 7. For example, six kinds of tube currents: 100 mA, 150 mA, 200 mA, 250 mA, 300 mA and 350 mA, and five kinds of tube voltages: 80 kV, 100 kV, 120 kV, 130 kV and 140 kV are set, and a plurality of X-ray irradiation condition candidates as combinations of these tube currents and tube voltages are previously prepared.
Next, an exposed dose calculating section 23 calculates an exposed dose (Step S103). The exposed dose is calculated by applying the X-ray irradiation condition to the attenuation model and the transmission thickness information of the specific in the same manner as the calculation of the image quality index, and obtained for each of the plurality of X-ray irradiation condition candidates.
When the image quality index and the exposed dose for each of the plurality of kinds of X-ray irradiation condition candidates are obtained in the above manner, X-ray irradiation condition information is then created by an X-ray irradiation condition information creating section 24 by the use of the plurality of X-ray irradiation condition candidates, and the image quality indexes and the exposed doses which correspond to those candidates (Step S104). In the present embodiment, the X-ray irradiation condition information is created in the form of a correlation table as an example shown in
The X-ray irradiation condition information according to this correlation table is displayed on the display unit in Step S105, and in subsequent Step S106, the radiographer selects an X-ray irradiation condition with reference to the correlation table displayed on the display unit. In such selection, the radiographer considers a variety of requirements such as an image quality and an operating condition of the X-ray CT apparatus according to a diagnosis purpose, and with all those considered, the radiographer selects one X-ray irradiation condition from the correlation table. When the X-ray irradiation condition is selected by the radiographer, with such a condition taken as a final X-ray irradiation condition, X-ray irradiation condition information is created by the X-ray irradiation condition information creating section 24, which is A-D converted by an X-ray irradiation condition display signal creating section 25, and displayed on the display unit 8 via the host computer 1 (Step S107).
Here, the tube current is controlled while it is taken into consideration that an average transmission length of X-rays in the object varies depending upon an irradiation angle of X-rays against the object. Namely, the control is taken such that the tube current is increased in the case of a large irradiation angle at which the transmission length is large and the tube current is decreased in the case of a small irradiation angle at which the transmission length is small, so as to keep an output of the detector at a constant level. The transmission thickness information acquired by the above-mentioned scanogram analysis is applied to the transmission length as a parameter in this case. Further, axes in the control are those in the axial direction Z and the rotational direction (view angle) Θ, and the tube current is modulated with respect to the parameters. The tube current in the X-ray irradiation condition set by the X-ray irradiation condition setting device 6 is used as a reference tube current in the modulation. For example, in the case of taking the reference tube current as the maximum value in the modulation control, when the maximum value is M and an amplitude modulation pattern is P(Z, Θ), the tube current I is expressed by the following expression (1):
[Formula 1]
I(Z,Θ)=M×P(Z,Θ) (1)
As thus described, the X-ray irradiation condition information created by obtaining an image quality index and an exposed dose for each of a plurality of X-ray irradiation condition candidates is presented to radiographer so as to allow the radiographer to set an X-ray irradiation condition based upon this X-ray irradiation condition information, thereby making it possible to set an X-ray irradiation condition based mainly upon the relation between the exposed dose and the image quality, with other requirements also appropriately considered, so as to set a more appropriate X-ray irradiation condition.
In the following, calculation of CNR to be used as an image quality index is described. When irradiated X-rays are I0, and an integral value of an absorption coefficient on a transmission path is “μ(E)×L”, transmitted X-rays I are expressed by a Formula (2):
[Formula 2]
I=∫I0(E)exp(−μ(E)×L)dE (2)
Further, data P used for reconstruction takes a ratio to the irradiated X-rays, and is expressed by a Formula (3):
[Formula 3]
P=−log(I/∫I0(E)) (3)
Here, assuming the attenuation model made up of the tissues a and b as in the example of
[Formula 4]
Pw=−log [∫I0(E)exp(μa(E)da+μb(E)db)dE/∫I0(E)dE] (4)
Pw0=−log [∫I0(E)exp(μa(E)(da+db))dE/∫I0(E)dE] (5)
C=Pw/Pw0 (6)
Here, the transmission length of Pw and the transmission length of Pw0 are “da+db” and thus equivalent. Further, the tissues a and b are, for example, water and a contrasted blood vessel, and defined for each of the foregoing attenuation models. For example, characteristic data μ(E) regarding X-ray energy and an absorption coefficient as shown in
With the contrast C obtained in the above manner, when an image noise is Nw0 and the attenuation model is circular, CNR is expressed by an expression (7):
[Formula 5]
CNR=C/Nw0 (7)
Here, when the attenuation model is oval as in the example of
Although the image noise Nw0 can also be estimated by calculation from a water equivalent thickness as the transmission thickness acquired by scanogram analysis and a scanning condition, the image noise Nw0 may be obtained by obtaining characteristics as shown in
Further, in the scanning protocol/attenuation model table of the example shown in
Although the exposed dose calculating section 23 is provided in the X-ray irradiation condition setting device 6 according to the present embodiment, the exposed dose calculating section 23 is not necessarily provided. In this case, Step S103 is omitted in
Further, although the scanning protocol is designated in the present embodiment, a tube current/tube voltage input screen 100 shown in
When a check has been inputted in the check box 103, an image quality index and an exposed dose are calculated also for each of combinations of tube currents and tube voltages previously registered in the X-ray irradiation condition database set in the external storage unit 7.
In a second embodiment, when at least one of an image quality index and an exposed dose which are desired by the user, combinations of tube currents and tube voltages that match the inputted condition are displayed. The user selects a tube current and a tube voltage to be used for actual scanning among those displayed.
Further, in the external storage unit 7, the correlation table of the CNR, exposed dose, transmission thickness, X-ray irradiation condition and scanning protocol in
Here, a case is described where the user inputs CNR as the image quality index.
The user inputs a desired value into the input field 141 for CNR or SNR as the image quality index, puts a mouse cursor 145 on the execution button 142 and clicks it. Thereby, a process shown in
In Step S201, the reading section 20 acquires the inputted CNR information and searches the correlation table of
In Step S202, transmission thickness information is acquired in the same manner as in Step S101.
In Step S203, the reading section 20 reads an X-ray irradiation condition candidate and a scanning protocol, which correspond to the X-ray irradiation condition candidate read in Step S201 and the transmission thickness information acquired in Step S202, from the correlation table of
In Step S204, the X-ray irradiation condition candidate and scanning protocol read by the reading section 20 in Step S203 is displayed on the display unit 8.
In Steps S205 and S206, an X-ray irradiation condition for use in scanning is selected from the X-ray irradiation condition candidates and then set as in the same manner as Steps S106 and S107.
According to the present embodiment, further preferable X-ray irradiation condition candidates and scanning protocols can be displayed based upon an image quality index value and an object transmission thickness that are desired by the user, and selection can then be made.
Although the image quality index was inputted on the condition input screen 140 of
In a third embodiment, a scanning protocol is edited and updated for each user, and an X-ray irradiation condition is selected and subjected to a display process based upon a scanning protocol set by the user.
In the present embodiment, a scanning protocol editing section is provided in addition to the components of the X-ray irradiation condition setting 6 according to the first and/or second embodiments.
The scanning protocol editing unit displays an ID input screen 160 of
When the user inputs a user ID, puts a mouse cursor 164 on the edition button 162 and clicks it, a scanning protocol/attenuation model table 170 of
When the scanning button 163 is clicked on the ID input screen 160, the processes of the first and second embodiments are performed based upon the scanning protocol corresponded to the user ID inputted in the ID input field 161.
According to the present embodiment, when scanning protocol is wished to be customized for each user as in a case where each user wishes to see a tissue of different size, it is possible for the user to display and set an X-ray irradiation condition based upon a scanning protocol edited and set by the user.
The present invention allows setting of a further appropriate X-ray irradiation condition mainly based upon a relation of an exposed dose of an object and an image quality, and the present invention is broadly applicable in the field of X-ray CT apparatuses for medical use.
Number | Date | Country | Kind |
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2005-107566 | Apr 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2006/306880 | 3/31/2006 | WO | 00 | 6/17/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/106941 | 10/12/2006 | WO | A |
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20040086076 | Nagaoka et al. | May 2004 | A1 |
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Number | Date | Country |
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1393681 | Mar 2004 | EP |
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2001-008930 | Jan 2001 | JP |
2004-73865 | Mar 2004 | JP |
Number | Date | Country | |
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20080240336 A1 | Oct 2008 | US |