RU177536U1 - DIGITAL X-RAY FLUOROGRAPHIC CAMERA - Google Patents

Abstract

The proposed technical solution relates to the field of medical technology, and more specifically to X-ray fluorographs used for screening diagnostics of diseases of the chest cavity. It is achieved by the fact that in a digital X-ray fluorography camera containing a light-tight housing protected by lead with an entrance window closed by a protective screen made of X-ray transparent and light-tight material, to which a flat-shaped fluorescent screen adjoins from the inside of the camera and is optically coupled by means of a fast lens with a digital photorecorder type connected to the electric signal processing unit, including a signal amplifier, analog-to-digital converter, pho circuit a digital image matrix, connected via a playback circuit to a video monitor, as well as an electric signal processing unit with a digital archive of test images, and a comparator with two inputs, one of which is connected through a switch to a archive of test images, and the other to a digital matrix of the current image and the output of the comparator is connected to the analyzer of the resulting signal, equipped with the indicator "Norm - pathology", while the processing unit of the electrical signal is connected to the control panel, on the external the surface of the protective screen, at its corners, at a distance of 20-25 mm from the nearest borders of the working radiation field, coordinate marks made of radiopaque material are fixed, and the electrical signal processing unit is supplemented by an electrical scaling diagram of the test image and the scheme of moving the test image relative to the current image in two mutually perpendicular directions.

Description

The proposed technical solution relates to the field of medical technology, more specifically to x-ray fluorographs used for screening diagnosis of diseases of the chest cavity.

A digital X-ray fluorography camera is known in which a memory screen deposited on a drum surface is used as a photodetector. After exposure, the reading of the latent image is carried out using an infrared laser (Copyright certificate No. 1018623, dated 13.10.82, АВВ 6/00) [1].

The use of a photodetector with a storage screen [1] allows one to reduce the radiation load on the patient by an order of magnitude (compared with a film fluorograph). However, this X-ray technology is extremely expensive. In our country, photo detectors with a storage screen are not available and are not used in the practice of phthisiopulmonology.

A digital X-ray fluorography camera is also known, comprising a photographic recorder including a fluorescent screen and an ultra-fast lens with a CCD matrix, mounted in a light-tight housing protected by lead, with an input window, a closed protective screen made of X-ray transparent and light-tight material, to which the fluorescent screen adjoins ( . - Edited by NN Blinov. - M .: Medicine, 2002. - S. 192) [2]. A digital X-ray fluorography camera [2] is part of a pulmonary fluorograph, for example, Renex-Fluoro, manufactured by the domestic company Gelpik.

The average effective dose received by the patient on the camera [2] is 50 μSv. This dose is much lower than on a film camera, which makes it possible to widely use a digital camera [2] for screening diagnostics of diseases of the chest cavity.

The disadvantage of a digital X-ray fluorography camera [2], as well as of all known analogues, is the absence in its design of an analytical system that provides machine diagnostics of digital images in the norm - pathology mode. The fact is that when screening for the diagnosis of diseases of the chest cavity, carried out for example to detect pulmonary tuberculosis at an early stage of the disease, the radiologist has to view a large number of images (up to 250) for a shift. Due to fatigue of vision, especially at the end of the shift, a pathology is viewed. According to statistics, this happens in 30% of cases, which of course is not permissible with such a formidable disease as tuberculosis.

The closest in design to the claimed object is a digital fluorographic camera containing a light-tight housing, protected by lead, with an input window, a closed protective screen made of X-ray transparent and opaque material, to which on the side of the camera there is a flat-shaped fluorescent screen optically coupled by means of a fast lens with a photographic recorder digital type connected to an electric signal processing unit including a signal amplifier, analog-to-digital converter a developer, a digital image matrix generation circuit connected via a playback circuit to a video monitor, and an electric signal processing unit contains a digital archive of test images, and a comparator having two inputs, one of which is connected through a switch to an archive of test images, and the other to digital matrix of the current image, and the output of the comparator is connected to the analyzer of the resulting signal, equipped with the indicator "Normal - pathology", while the processing unit of the electrical signal is connected to the remote in management (Utility Model Patent No. 1177792 dated 02/08/2012 [3].

The analogue [3] was chosen by us as a prototype.

A digital camera [3] greatly facilitates the work of a radiologist, as it allows the automatic detection of possible pulmonary pathology on an x-ray.

The disadvantage of the prototype [3] is expressed in the low accuracy of detection of pathology. One of the reasons for this is the absence of a comparator adjustment element in the digital camera [3], in which the current X-ray image is compared with the test image. The fact is that in a comparative analysis of these images, they must coincide both in scale and in position. This can be achieved by adjusting the comparator. The lack of such a possibility in the prototype reduces the accuracy of the digital camera [3].

The aim of this work is to equip the digital X-ray camera with adjustment elements of the comparator.

The technical result of the utility model is expressed in the expansion of technical means of machine X-ray diagnostics. It is achieved by the fact that in a digital X-ray fluorography camera containing a light-tight housing protected by lead with an entrance window closed by a protective screen made of X-ray transparent and light-tight material, to which a flat-shaped fluorescent screen adjoins from the inside of the camera and is optically coupled by means of a fast lens with a digital photorecorder type connected to the electric signal processing unit, including a signal amplifier, analog-to-digital converter, pho circuit a digital image matrix, connected via a playback circuit to a video monitor, as well as an electric signal processing unit with a digital archive of test images, and a comparator with two inputs, one of which is connected through a switch to an archive of test images, and the other to a digital matrix of the current image, and the output of the comparator is connected to the analyzer of the resulting signal, equipped with an indicator "Normal - pathology", while the processing unit of the electrical signal is connected to the control panel, externally the surface of the protective screen, at its corners, at a distance of 20-25 mm from the nearest borders of the working radiation field, coordinate marks made of radiopaque material are fixed, and the electrical signal processing unit is supplemented by an electrical scaling diagram of the test image and the scheme of moving the test image relative to the current image in two mutually perpendicular directions.

Further description is accompanied by drawings and explanations to them. In FIG. 1 is a block diagram of a digital X-ray fluorography camera; FIG. 2 shows the location of the coordinate marks on the protective screen, and FIG. 3 shows the basic elements of an electric signal processing unit.

The digital X-ray fluorography camera contains a light-tight housing 1, protected by lead, with an entrance window closed by a protective shield 2 made of X-ray transparent and light-tight material, for example aluminum, to which a flat-shaped fluorescent screen 3 adjoins from the inside of the camera and is optically coupled by means of a fast lens 4 with a photo recorder 5 digital type (CCD matrix) connected to the electric signal processing unit 6. The electric signal processing unit 6 is connected to the control panel Alert 7, made in the form of a keyboard to a microprocessor located in the body of the control panel 7. A video monitor 8 is also connected to the control panel 7, connected to the electric signal processing unit 6 and an x-ray generator 9 connected to the x-ray emitter 10.

On the outer surface of the protective screen 2, at its corners, at a distance of 20-25 mm from the nearest borders of the working field of irradiation 11, coordinate marks 12 _A , 12 _V , 12 _C , 12 _{D are} fixed, made of radiopaque material, for example lead, having, for example , the shape of a ring made, for example, from a wire with a diameter of 1-1.5 mm, with a central ball with a diameter of 2-2.5 mm (Fig. 2).

The electric signal processing unit 6 contains an amplifier 13, coming from the digital photorecorder 5 (Fig. 3), an analog-to-digital converter 14, a digital image matrix forming circuit 15 ₁ connected through a playback circuit 16 and a switch 17 switched by the keyboard of the control panel 7 to video monitor 8. Cell 15 _{2 is} designed to store digital x-ray images taken during a shift and to be analyzed. The choice of a particular image is carried out by the radiologist using the keyboard of the control panel 7. The electric signal processing unit 6 also includes an archive of test images 18 and a comparator 19, which has two inputs, one of which is connected to the archive of test images 18. This connection is made through the switch 20, the scaling circuitry of the digital image 21 and the circuitry 22 for moving the test image in two mutually perpendicular directions. The switch 20 and the electrical circuits 21, 22 are connected through the switch 23 to the control panel 7 and are controlled by its keyboard. The second input of the comparator 19 is connected to a digital image matrix forming circuit 15 ₁ . The output of the comparator 19 is connected to the analyzer of the resulting signal 24, equipped with an indicator 25 "Norm (n) - pathology (p)".

The proposed digital X-ray fluorography camera is designed to work as part of a digital pulmonary fluorograph, for example, Renex-Fluoro company Gelpik. Her work is based on comparing - comparing the images of the current and test images. In a comparative analysis of these images, they should coincide both in scale and in position. This can be achieved by adjusting the comparator. Note that all test images should be performed on the same digital pulmonary fluorograph equipped with a digital camera with coordinate marks 12 _A , 12 _V , 12 _C , 12 _D. All test images are stored digitally in the archive 18.

Adjustment of the comparator 19 is as follows. First, a digital picture is taken without a patient on a digital fluorograph, which shows the coordinates of 12 _A , 12 _V , 12 _C , 12 _D. A digital image of these coordinate marks from cell 15 ₁ is entered into the comparator 19 and displayed on the screen of the video monitor 8. Then, from the archive 18, any of the test pictures is entered into the comparator 19 (all test pictures stored in the archive 18 are geometrically interconnected). The image of the test image entered into the comparator 19 is also displayed on the video monitor 8. After that, the radiologist using the keyboard of the control panel 7 moves the test image on the video monitor 8 (changing its scale if necessary) until the image of its coordinate marks 12 _A , 12 _V coincides, 12 _C , 12 _D with the image of the coordinate marks of the current image entered into the comparator from cell 15 ₁ . After this operation, in the comparator 19, the current and test images will coincide with each other both in scale and in position. The comparator 19 must be adjusted at least once a month.

Digital X-ray fluorography camera in practical work is used as follows. After performing fluorography, the current image of the lungs is displayed on the screen of the video monitor 8 for preview. In the absence of obvious pathological changes on it, the radiologist proceeds to the second stage of the analysis. To do this, using the keyboard of the control panel 7, the radiologist enters into the microprocessor data (age, gender of the patient, his physique, fluorography modes) necessary for selecting a test image. The test image of the lungs, characterizing the norm, is stored in the archive of test images 18 and is used as a reference. Next, the radiologist sets the location and size of the measurement site, for example, the upper lobe of the right lung, the diameter of the measurement site is 40 mm. After that, on a command from the control panel 7, this section of the test image is entered through the switch 20 into the left input of the comparator 19, and a similar section of the current image is entered into the right input of the comparator 19; it comes from a digital matrix 15 ₁ . The comparator 19 compares the relative brightness values of the selected areas of the test and current digital images (the relative brightness value is defined as the difference between the brightnesses of the target area and the clean, unshaded patient). The analyzer 24 of the resulting signal determines the deviation in brightness of the measured portion of the current image from the test. If the relative brightness of the current image deviates from the test image to 3%, the current image is considered normal and the letter n lights up on indicator 25. If the measurement result exceeds this value (more than 3%), then the letter p appears on indicator 25 (indicating a possible pathology). In this case, the radiologist proceeds to a more thorough analysis of the current image of the lungs.

Claims (1)

A digital X-ray fluorography camera containing a light-proof housing protected by lead with an entrance window closed by a protective screen made of X-ray transparent and light-tight material, to which a flat-shaped fluorescent screen adjoins from the inside of the camera and is optically coupled by a fast lens with a digital photorecorder connected to the processing unit an electric signal including a signal amplifier, an analog-to-digital converter, a digital matrix generation circuit The image is connected via a playback circuit to a video monitor, as well as an electric signal processing unit with a digital archive of test images and a comparator having two inputs, one of which is connected through a switch to the archive of test images, and the other to a digital matrix of the current image, and the output the comparator is connected to the analyzer of the resulting signal, equipped with an indicator "Normal - pathology", while the processing unit of the electrical signal is connected to the control panel, characterized in that on the external The surface of the protective screen, at its corners, at a distance of 20-25 mm from the nearest borders of the working radiation field, coordinate marks made of radiopaque material are fixed, and the electrical signal processing unit is supplemented by an electrical scaling diagram of the test image and the scheme of moving the test image relative to the current image in two mutually perpendicular directions.

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