DE102006037969A1 - Method for x-ray imaging under application of subtraction technology, involves recording x-ray image of examination area by detector dose, where multiple other x-ray images of examination area are recorded by another detector dose - Google Patents

Abstract

The method involves recording an x-ray image of an examination area by a detector dose (D1). Multiple other x-ray images of the examination area are recorded by another detector dose (D2), and with which the image data of the former x-ray image and the image data of the latter x-ray images are subtracted form each other to obtain multiple subtraction images. The former detector dose is selected greater than the latter detector dose.

Description

The The present invention relates to a method for X-ray imaging using a subtraction technique in which a first first x-ray picture an examination area with a first detector dose and at intervals, several more X-ray images of the examination area with each recorded a second detector dose, and at the image data of the first X-ray image and image data of the further X-ray images from each other are subtracted to obtain multiple subtraction images.

In X-ray imaging it is desirable in some applications, especially in the Observation time-variable operations hide the static background from the pictures. This is possible achieve using a subtraction technique. Thus, for example. in the X-ray based, scenic, medical imaging subtraction method used around the for the diagnosis and therapy unimportant and disturbing anatomical background to remove. examples for these techniques are the digital subtraction angiography and the Pathfinder technology.

Basically includes a subtraction method two phases. In the first phase, the so-called mask phase, a first x-ray image (mask image) of the generated area to be examined, in which the area under investigation object to be detected or the change to be detected still included or not yet recognizable. In the subsequent second Phase, the so-called filling phase, Now there are more x-rays (Filling pictures) generated in which the object to be detected is recognizable. By digital subtraction of the mask image and the respective filling images Subtraction images are obtained on which only the one to be detected Object or the change to be detected are recognizable.

By the subtraction of the images eliminates all image content that are present both in the mask image and in the filling image. This allows for improved visibility of the differences between the pictures, d. H. improved visibility of the to be detected Object or the change to be detected.

So For example, in digital subtraction angiography blood vessels of the human body be captured and presented. The mask image is here before the injection of a contrast agent, so that the vascular structure in the first x-ray barely different from the background. In the second phase will be then more radiographs of the same area recorded while an X-ray sensitive contrast agent injected to highlight the vessels becomes. In the subtraction pictures, only the vessels are visible during overlays from other X-rays Absorbing structures such as bones by the subtraction Have disappeared.

One Another example is the scouting technique, which is selective for Catheterization of vessels at interventional therapy. In such vascular interventions becomes the current position of an X-ray absorbing catheter by fluoroscopy in a two-dimensional x-ray image shown. In addition the blood vessel as so-called. To recognize the roadmap At the beginning of the intervention, a mask image is recorded which was injected with a small amount of contrast agent. The following, Fluoroscopy images obtained without injection of a contrast agent put the filling pictures which are each subtracted from the mask image. On the subtraction pictures then the catheter is bright over recognizable by the dark blood vessel, the background being eliminated by the subtraction.

In The second phase of a subtraction procedure often becomes multiple Images recorded at intervals, as a rule, a temporally changeable Operation to be detected. This is the contrast agent in applications of medical imaging all the time in the river and fills never open the entire vascular tree once out, so for the illustration of the vascular tree several x-ray pictures required are. Also in scouting technique are several radiographs at intervals as filling pictures recorded as the guidewire while navigates an intervention to a specific point in the vascular tree becomes.

In X-ray based medical imaging, as well as in other applications of X-ray imaging, noise is a significant factor in image quality. Since the radiation dose should be as low as possible in medical imaging, X-ray images contain a greater or lesser amount of noise, mainly Sequence of the quantum nature of the X-ray radiation is. The quantum noise is subject to the following law: When changing the detector dose, ie the X-ray energy absorbed during the image acquisition in the X-ray detector by the factor x, the variance V (square of the standard deviation) of the noise scales by a factor of 1 / x, provided that the average image brightness is constant is held. The total detector dose is so far distributed evenly on all X-ray images in the subtraction technique. When subtracting two noisy images, the error propagation law applies, so that the respective subtraction images created are of higher noise than the underlying ones Have X-ray images.

The The object of the present invention is a method for X-ray imaging using a subtraction technique with which the noise in the subtraction pictures opposite the previously known methods for the same total detector dose can be reduced.

The Task is solved by the method according to claim 1. advantageous Embodiments of the method are subject matter of the subclaims or can be the following description and the embodiment remove.

at the present method for X-ray imaging using a subtraction technique is in a known manner first a first x-ray image an examination area as a mask image with a first detector dose recorded. At a later time then several more radiographs of the examination area as filling pictures recorded in each case with a second detector dose in which an object to be detected or changes to be detected across from the first x-ray image are recognizable. Image data of the first X-ray image and image data of further x-rays are then subtracted from each other to form multiple subtraction images to obtain. The present method is characterized that the first detector dose higher chosen as the second detector dose becomes.

at In the present method, therefore, the detector dose is not uniform all x-rays distributed. Rather, the mask image with a higher detector dose and the subsequent ones filling images recorded with a correspondingly lower detector dose. By this procedure leaves the noise in the subtraction images is opposite to the reduce previous technique in which all X-ray images, d. H. both mask image as well as filling pictures, were recorded with the same detector dose.

In this case, it was recognized that, taking into account the laws of error propagation by suitable distribution of the detector doses, the noise in the subtraction images can be lowered or optimized. If D is the sum of all detector doses of phase 1 and phase 2, let a · D = D1 be the detector dose for the mask image and let b be the number of X-ray images for phase 2 (filling images), the variance V of the subtraction images is proportional to 1 / (a * D) + b / (1-a) / D. This variance will be minimal if ( a = 1 / √ b + 1 ). The larger the number b of the further X-ray images in phase 2, the greater should therefore be the detector dose D1 of the mask image. Optimum results are achieved if the above minimum variance equation is met, ie, if the first detector dose D1 = D / (√ b + 1) and the second detector dose D2 = (D-D1) / b are selected.

With In the present method, the image quality can be at the same total detector dose elevated Being a good relative in medical X-ray imaging Measure of patient dose is, provided on the X-ray spectrum between mask and filling phase nothing changes. In the same way, even with constant image quality, the detector dose and thus the patient dose are lowered. With the present Procedure leaves thus the noise of the subtraction images at the same total detector dose across from reduce the known method.

The different detector doses for the first and the other radiographs be by varying the irradiation intensity of the examination area set. This can, for example, by a change in the tube current or the exposure time can be achieved.

The Method can also be used in a control device of a system for X-ray imaging be implemented. In this case, an interface, for example, via a graphical user interface, provided by an operator of the plant inputs the total number of X-ray images to be recorded. alternative can also choose from a variety of recording programs be specified with different numbers of X-ray images, from which the user then selects one. The default of the total detector dose can done in the same way as already in the previous X-ray equipment medical imaging is performed. Based on the total detector dose and the number of X-ray images to be created calculates a program module in the control device then the detector dose for the mask image and the detector doses for the filling pictures and controls the x-ray system when recording the mask and fill images accordingly.

The The present method will now be described with reference to an exemplary embodiment briefly explained in connection with the drawings. in this connection demonstrate:

1 an example of a C-arm device as an imaging system for carrying out the present method; and

2 an example of the procedure in the implementation of the present method.

The following is the present Verfah ren described by way of example with reference to an X-ray angiography. The X-ray angiography system is shown schematically in FIG 1 shown. It consists of a two-axis rotatable C-arm 1 at which an x-ray tube 2 and an X-ray detector opposing the X-ray tube 3 are attached, an image processing unit 4 and an image display unit 5 , Furthermore, this system includes the motorized patient table 8th and a control unit 6 for image capture control. This control unit 6 includes a calculation and control module 7 that the x-ray tube 2 or a pre-filter device arranged in front of it for generating different detector doses during the recording of the mask image and the filling images according to the present method. By rotation of the C-arm 1 can be different projections of the examination area during the examination on the patient table 8th stored patients 9 record as two-dimensional images.

In carrying out the present method, whose procedure is shown schematically in 2 is shown, first the total detector dose D and the number of filling images b are given. In the present example, nine x-ray images are to be recorded as filling images. In the subsequent calculation step, the first detector dose D1 for the recording of the mask image is calculated. The calculation yields a detector dose D1 corresponding to 25% of the total detector dose D. The images of the subsequent filling phase are then recorded with (1 - 0.25): 9 = 8.33% of the total detector dose. As a result, an optimal difference in the detector dose between mask image and filling image of a factor 3 is maintained during image recording, which leads to a minimum noise (given the total detector dose) in the nine subtraction images generated later.

The Control unit controls the C-arm device to record the mask image with the calculated detector dose D1. After the injection of a suitable contrast agents are spaced nine times filling images in turn, with the detector doses for these filling images in turn the control unit can be adjusted. After recording the filling images a digital subtraction of the image data of the mask image takes place from the respective filling picture, around the associated To obtain subtraction image. The subtraction takes place in the image computer the angiography system. The subtraction pictures become the user displayed on the image display device.

The present method leaves of course not just with the C-arm device, which is given by way of example. For the implementation of the Method are rather all X-ray based, can be used in medical and non-medical imaging devices, for themselves the subtraction technique are suitable.

Claims (4)

Method for X-ray imaging using a subtraction technique, in which first a first X-ray image of an examination area with a first detector dose D1 and at intervals a plurality of further X-ray images of the examination area are recorded with a second detector dose D2, and in the image data of the first X-ray image and image data of the other X-ray images be subtracted from each other to obtain a plurality of subtraction images, characterized in that the first detector dose D1 is selected to be higher than the second detector dose D2. Method according to claim 1, characterized in that that the ratio between first detector dose D1 and second detector dose D2 a higher one Number of additional x-ray images is higher than a small number. A method according to claim 1 or 2, characterized in that the first detector dose D1 and the second detector dose D2 are selected according to the following equation: D1 = D / (√ b + 1) D2 = (D - D1) / b where b is the total number of further X-ray images and D is the total sum of the detector doses of the first and the further X-ray images. Method according to one of claims 1 to 3, characterized that the different detector doses by different Tube currents one for the X-ray imaging used X-ray tube and / or be generated by different exposure times.