RU123312U1 - X-RAY DIAGNOSTIC DIGITAL APPARATUS - Google Patents

Abstract

X-ray diagnostic digital apparatus containing an X-ray emitter, a filter of X-ray radiation scattered by an object, a digital receiver-converter of an X-ray image in the form of a matrix consisting of many pixels, and means for software processing of an X-ray image, characterized in that the filter of scattered radiation is a flat panel located in front of the object of study, consisting of a base made of an X-ray transparent material, with embedded marks made of X-ray absorbing material, the marks are made with a size commensurate with the dimensions of the pixels of the digital image matrix, and are located at a distance of at least 15-20 pixels from each other, while means for software processing of the X-ray image are additionally equipped with a package of applied programs that provide the construction of the distribution of scattered radiation in the image plane and subtracting it from the image pixels, averaging the signals de Tectors recording scattered radiation in the vicinity of the elements.

Description

The utility model relates to x-ray technology and can be used in x-ray diagnostic practice to reduce radiation exposure during the study without compromising the quality of the digital image.

One of the distinct trends in the development of modern X-ray diagnostic equipment in recent years is the widespread use of systems that provide digital conversion of an X-ray image, reconstructive tomography using a single-turn conical working beam of radiation and a two-dimensional matrix of digital detectors - the so-called tomosynthesis systems, often compatible with various types of digital x-ray machines (such as the "C-arm", mammography, type BRS (Basic Radiography system - "basic radiographic system"):

Blinov N.N., Varshavsky Yu.V. et al. Comparative analysis of dose loads on patients during cardiovascular studies using computed tomographs and angiographic complexes. M .: "Radiology and practice", No. 3, 2009, pp. 30-40.

Zelikman MI, Kruchinin S.A. Comparative analysis of various methods for evaluating effective doses using x-ray computed tomographs. M .: "Medical equipment", No. 5, 2009, pp. 7-12

Such devices make it possible to obtain a full-size 3D image in sizes of up to 30 × 30 × 30 cm ³ / in a single study in a few seconds with a radiation dose lower than the dose with multislice spiral tomography, but also very significant.

The main disadvantage of modern x-ray digital devices, both for radiography and for tomography, is the low image quality caused by the harmful effect of the radiation scattered by the object on the signal-to-noise ratio.

The developers and manufacturers of x-ray equipment have taken measures to reduce the dose as much as possible during x-ray studies. Several systems have been created that provide a sufficiently significant reduction in the effective dose.

For example, dose reduction systems suitable for tomosynthesis are known:

ASIR (Adaptive Statistical Iterative Reconstruction) "General Electric" is a new iterative reconstruction program that allows you to reduce the dose by more than 50% while maintaining image quality and improving low contrasts.

iDose “GE-Healthcare”, “Philips” - is an iterative reconstruction program that works in conjunction with other methods of dose reduction, including optimal external filtering for the distribution of radiation depending on the thickness of the organ under study, the use of detectors providing a high signal to noise ratio, application collimators that reduce the effect of scattered radiation, the use of an automatic current control system depending on the size and density of the object of study. The total dose reduction in the Philips system is up to 80%. Philips provides a real-time dose control system for personnel working in surgical interventions under X-ray control with color markers on the monitor screen indicating dose hazard.

Care-Dose "Siemens" - a set of measures to reduce the dose.

The automatic current control system (Care-Dose 4D) provides the necessary minimum dose for deviations of the patient's size from the average, at different angles of rotation, with different planes of scanned organs.

In recent years, international recommendations have been applied in the Russian Federation to determine dose levels in CT, which provide not only methods for assessing the so-called parameter of the CTDI dose index in CT (GOST R IEC 60601-2-44-2005, IME h. Particular safety requirements for X-ray computer tomographs (IEC 60601-2-44)), and means for its determination (cylindrical phantoms from polymethylmethacrylate 32 cm in size (whole body) and 16 cm (head)) and a dosimeter with a finger camera).

The introduction of the dose minimizing systems described above into CT scanners makes the CTDI dose index determined using a cylindrical phantom undefined.

The fact is that with the help of a uniform phantom of a cylindrical shape, it is impossible to take into account changes in the radiation power during scanning created by changes in the density of the object, the angle of inclination of the emitter-detector system. The effect of optimal spatial filters on reducing the radiation dose in a cylindrical object is also not equivalent to the shape of the human body.

Thus, the CTDI values specified in the operating documents prescribed by GOST R IEC 60601-2-44-2005 do not contain information about the actual dose loads obtained during the study.

So closer to the shape of the chest and the entire torso of the human body is an ellipsoidal phantom. A cylindrical phantom with a diameter of 16 mm is suitable for the head.

Similar reasoning can also be attributed to systems for tomosynthesis and, to a certain extent, to digital radiography

Deterioration in image quality is determined by an increase in the fraction of scattered radiation caused by the expansion of the working beam opening angle and the need to complicate the reconstruction program to account for the deviation of the angles of incidence from the right angle. A high proportion of scattered radiation affects the increase in dose and reduces the signal-to-noise ratio.

Thus, the excessive pursuit of the number of slices in modern computer tomographs (300 or more) can hardly be considered justified. From a diagnostic point of view, the most important parameter in CT is the time of the study, and not the number of sections at all.

In the near future, we should expect a significant expansion of the scope of tomosynthesis systems: devices where a flat 2D digital matrix is used to obtain computed tomography, performing a complete three-dimensional reconstruction of a body section up to 30 × 40 cm in one revolution or part of it. Those reduction systems are applicable here radiation doses and reconstruction improvement programs designed for helical multi-detector CT. Reducing the harmful effects of scattered radiation is a decisive task in such systems.

The closest analogue (prototype) to the proposed utility model is a device for obtaining an X-ray image, including a radiation source, a scattered radiation filter in the form of a screening raster installed behind the object of study, a digital receiver-converter in the form of a matrix consisting of many pixels and means for software processing X-ray image (see "X-ray diagnostic apparatus", in 2 volumes, under the editorship of NN Blinov and B.I. Leonov, M., VNIIIMT, 2001)

The introduction of a screening raster reduces the fraction of scattered radiation to 70-75% and direct beam radiation to 25-30%, which increases the dose to the patient and does not completely eliminate the harmful effect on image quality. In addition, the screening raster is a rather expensive and technically complex device that increases the cost of manufacturing an X-ray diagnostic apparatus.

The technical task of the utility model is to improve the quality of visualization of x-ray images due to the registration of radiation scattered by the object of the x-ray study.

The technical problem is achieved in that in an X-ray digital apparatus comprising an X-ray emitter, a filter of an X-ray scattered radiation by an object, a digital receiver-transducer of an X-ray image in the form of a matrix consisting of a plurality of pixels, and means for programmatically processing an X-ray image, a scattered radiation filter installed in front of the object is a flat panel consisting of a base made of x-ray transparent material, with built-in the marks are made of X-ray absorbing material, the marks are made in a size commensurate with the pixel size of the digital image matrix, and are located at a distance of at least 15-20 pixels from each other, the means for programmatically processing the X-ray image are additionally equipped with an application package that ensures the distribution of scattered radiation in image plane and subtracting it from the image pixels, averaging the signals of the detectors registering the scattered radiation over the neighborhood of the element Comrade.

In essence, the proposed technical solution is intended to reduce the harmful effect of scattered radiation on image quality, which consists in constructing a scattered radiation field directly during exposure. It is based on the possibility of frequency separation of signals from scattered and direct radiation from an object.

Studies show that the distribution of scattered radiation from almost all medical objects along the image plane is characterized by low spatial frequencies, not exceeding 0.1 p / cm. Meanwhile, the Nyquist frequency in medical digital x-ray converters is 2.5-5 ppl / mm, i.e. 2 orders of magnitude higher.

The filter attenuates not only direct but also scattered radiation. In this case, it becomes necessary to experimentally take into account the scattered radiation absorbed by the filter from the image plane.

The filter size is selected depending on the pixel size of the digital detector and should be about 2 × 2 pixels. For a given spatial frequency of the filters, the number of sensitive pixels in the digital matrix of the detectors recording scattered radiation located behind the filter does not exceed 1% of the image area.

Constructing a scattering field in the image plane is not particularly difficult by software, highlighting scattering pixels by signal levels. Next, the scattering field is subtracted from the digital image on which the scattering pixel systems after subtraction are averaged between four adjacent working pixels.

There is reason to believe that subtraction of the scattering field from each intermediate image obtained by digital radiography and during the process of CT tomosynthesis will lead to a significant increase in the signal-to-noise ratio, and, therefore, ceteris paribus, a dose reduction without loss of quality.

The proposed utility model is illustrated by drawings, in which Fig. 1 shows a general diagram of an X-ray diagnostic apparatus in working condition when conducting research on an object of research, Fig. 2 is a structural diagram of a scattered radiation filter, and Fig. 3 is a sectional view of a flat filter panel.

The proposed X-ray diagnostic apparatus contains an X-ray power device 1, an X-ray emitter 2, a scattered radiation filter 3. During the study, the object of study 4 is located between the scattered radiation filter 3 and the digital receiver-converter of the x-ray image 5. The digital receiver-converter 5 is connected to the workstation 6 and digital monitor 7.

The digital receiver-converter of the x-ray image 5 is made in the form of a matrix consisting of many pixels.

Means for software processing of the x-ray image can be presented, for example, in the form of an automated workstation 6 of a radiologist.

To ensure the implementation of the claimed technical solution of the means for software processing of the x-ray image, in particular, the radiologist's workstation 6 is equipped with a package of application programs that ensure the distribution of scattered radiation in the image plane and subtract it from the image pixels, averaging the signals of detectors recording scattered radiation in the vicinity elements.

The scattered radiation filter 3 (see FIG. 2 and FIG. 3) is a flat panel consisting of a base 8 made of X-ray transparent material, with marks 9 made of X-ray absorbing material embedded in it. For example, marks 9 can be made lead.

Labels 9 are made in a size commensurate with the size of the pixels of the digital image matrix, and are located at a distance from each other of at least 15-20 pixels.

The proposed device operates as follows:

The scattered radiation filter 3 (Fig. 1) partially absorbs a direct x-ray beam using lead marks 9 (Fig. 2. Fig. 3), creating information about the amount of scattered radiation behind the object of study 4. This information is transmitted to the digital receiver 5 and programmatically it is processed by the AWP 6 computer by subtracting the amount of scattered radiation from the total x-ray flux. Thus, a reduction in the harmful effects of scattered radiation on the quality of the x-ray image is achieved, increasing the signal-to-noise ratio.

The proposed device and the software method for filtering scattered radiation, implemented by the proposed device, will not degrade the quality of the final 3D image, since each intermediate subtraction of scattering is performed at different angles. This method is applicable not only in computed tomography and tomosynthesis, a positive effect can be achieved with any kind of digital radiography, including the use of photostimulated phosphors.

The proposed device that implements a software method for filtering scattered radiation may be a more effective means of improving image quality than a raster and lead to the rejection of rasters. The undoubted advantage of the proposed technical solution is the reduction of the so-called "Buki factor" - the coefficient of increase in exposure when applying a raster. This coefficient ranges from 2.5 to 5, depending on the parameters of the raster. There is reason to believe that in the considered technical solution for digital radiography, the Buki coefficient will be close to unity, and the loss of information due to pixels recording scattering should not exceed 0.02%.

Thus, the main advantage over the known devices is that in this design there is no need to use a screening raster (used to date as a structural element of all types of x-ray machines), while the x-ray radiation intensity necessary for high-quality visualization of x-ray images due to registration of radiation scattered by the object of x-ray research.

Claims (1)

An X-ray digital apparatus comprising an X-ray emitter, an X-ray filter of an object scattered by an object, a digital X-ray image receiver-converter in the form of a matrix of a plurality of pixels, and means for programmatically processing an X-ray image, characterized in that the scattered radiation filter is a flat panel located in front of the object of study, consisting of a base made of X-ray transparent material, with a mark embedded in it made of X-ray absorbing material, the marks are made in a size commensurate with the pixel size of the digital image matrix, and are located at a distance of at least 15-20 pixels from each other, while the means for programmatically processing the X-ray image are additionally equipped with an application package that provides the construction of the distribution of scattered radiation in the image plane and subtracting it from the image pixels, averaging the signals of the detectors registering the scattered radiation over the neighborhood of the elements comrade