X-ray or gamma ray systems or devices – Specific application – Computerized tomography
Reexamination Certificate
2000-11-21
2002-09-17
Kim, Robert H. (Department: 2882)
X-ray or gamma ray systems or devices
Specific application
Computerized tomography
C378S004000
Reexamination Certificate
active
06452997
ABSTRACT:
This invention relates to a method, apparatus and their use for tomographic imaging, particularly for producing complex motion or spiral tomography images in medical x-ray imaging according to the preambles of the appended independent claims.
BACKGROUND
Imaging methods utilizing electromagnetic radiation can be divided into two groups: radioscopic methods and tomographic methods. In traditional radioscopy the radiation source, the object to be imaged and the radiation detector, e.g. an x-ray film, are stationary with respect to one another during the imaging session. Imaging methods in which a narrow beam is moved over the object to be imaged are also known.
Tomographic methods can be divided into linear (i.e. planar) tomographic methods and complex motion or spiral tomography methods. In tomographic imaging the object to be imaged and/or the radiation detector are moved with respect to each other in a controlled manner, and thus in linear tomography the tomographic movement occurs with respect to one axis and in complex motion tomography with respect to two axes. These methods use a beam which is of the same size as the object to be imaged, and the object is usually held in place as the radiation source and radiation detector are moved dependently on each other on the opposite sides of the object to be imaged in the opposite directions so that the beam penetrates the object from different directions, but its centre of movement/rotation in the object does not move. The methods provide accurate images of the imaging area in the centre of rotation of the beam, whereas the other parts of the object are blurred partially or totally.
There are also ‘narrow beam tomography’ methods in which a beam considerably narrower than the object to be imaged sweeps across the area to be imaged and the beam is turned with respect to the object to be imaged. In that case the imaging means (radiation source and radiation detector) must be moved in a controlled manner so that the detector moves in relation to the beam at a lateral velocity which corresponds to the perpendicular sweeping speed of the beam in the area to be imaged multiplied by the ratio of magnification, i.e. by a coefficient which is the ratio of the distance of the beam focus (=radiation source) and the distance of the focus from the area to be imaged. Here the term detector refers to a film or the like; in digital imaging, for example, the movement of the detector with respect to the area to be imaged may be replaced with a suitable electrical function, such as charge transfer on the surface of a semiconductor sensor.
Thus it is known to use both horizontal and vertical movement of the imaging means for producing a tomographic effect. Many prior art devices that enable complex motion paths have very large structures, and thus it may not be possible to move the imaging means rapidly and change their direction due to the limits set by the general physical principles of moving heavy masses and mechanical solutions of the devices. Against this background it is not easy to develop commercially feasible devices.
The present trend is to develop solutions which allow to use the same device for various purposes, i.e. the goal is to be able to use the same device in different tomographic methods and for imaging different projections. When the same device has different imaging modes, investment in imaging sensors based on modern digital technology becomes more profitable, which lowers the threshold of introducing them. Digital technology facilitates the doctors' work, for example, since it does not only allow the doctors to produce better images than earlier and thus to make more accurate diagnoses, but also to store the images and manage them in electronic form, together with all other documents related to the patient.
One prior art tomographic imaging device, which has relatively many different imaging modes, is disclosed in Finnish Patent 88671. In one embodiment according to the publication the imaging means of the device are attached to the ends of a suspension arm that can be rotated horizontally, the arm being provided with a degree of freedom for moving in the direction of the axis between the imaging means. Furthermore, the arm can be tilted with respect to the horizontal plane. According to the publication, the imaging means can also be arranged so that they can be moved vertically with respect to the object to be imaged by forming the suspension arm in the shape of an arc and by moving the arm in the direction of its longitudinal axis along a supporting structure in which the imaging means move upwards along a curved path of the arm and correspondingly downwards on the opposite sides of the object to be imaged.
The solution according to the publication utilizes a narrow beam, and the imaging means are moved vertically with respect to the object to be imaged in order to obtain a perpendicular cross-sectional image of the patient's teeth which are diagonal to the vertical plane. Thus the publication does not disclose use of the solutions described therein (which is known per se from other contexts) for actual complex motion or spiral tomography imaging, i.e. the use of the movements the structures in question enable for producing a tomographic effect with respect to two axes during radiation. On the other hand, the use of the solutions disclosed in the publication for complex motion tomographic imaging as such is somewhat problematic, because the quality of the image has to be compromised. As a result of the fact that the detector is moved along a curved path with respect to the object to be imaged by keeping it all the time perpendicular to the radiation source, i.e. parallel with the tangent of the path, the shear plane to be projected onto the detector changes constantly in the object to be imaged. Naturally, the resolution of the image produced in this way is not the best possible one.
SUMMARY OF THE INVENTION
According to the basic idea of the invention disclosed in this application, a curved path is arranged for the radiation source of the imaging apparatus in the vertical direction with respect to the object to be imaged, e.g. by attaching the radiation source substantially to one end of a curved suspension arm and by attaching the other end of the arm to the imaging apparatus either stationarily or so that the arm can be moved in the direction of its longitudinal axis, in which case the curved movement can be produced either by moving the radiation source along a guide track in the arm, for example, or by moving the arm in the direction of its longitudinal axis along a stationary supporting structure in the vertical direction with respect to the object to be imaged. Naturally there are numerous ways of producing such a curved movement. For example, the suspension arm does not need to be curved, but the radiation source can be moved e.g. by moving a pivoted suspension arm programmatically. The radiation source may also be placed inside a casing or the like so that the curvature of the vertical movement cannot be detected from outside.
The counter-movement of the curved movement in the vertical direction of the radiation source is implemented according to the invention by moving the radiation detector substantially linearly on the opposite side of the object to be imaged with respect to the radiation source. In that case the distance of the detector from the object to be imaged changes slightly during the imaging session, which causes a theoretical change in magnification. This error, however, lacks practical relevance in the case of the layer thicknesses that are normally imaged with the solutions according to the invention.
According to the invention it is also particularly preferable to keep the detector constantly parallel with one shear plane that is to be imaged from the object in a manner known per se. In the direction of the vertical movement this parallelism is achieved automatically when the inventive method is used. If this mode known per se were to be implemented in solutions known from Finnish
Jarva Mikko
Müller Timo
Kiknadze Irakli
Kim Robert H.
Nixon & Vanderhye P.C.
Planmeca Oy
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