RU2171629C1 - Digital scanning mammograph - Google Patents

Abstract

FIELD: devices for radiodiagnosis with scanning of the examined object by a narrow beam of X-radiation, applicable in mammography for determining the position of low non-palpable injuries of the mammary gland differing in density and diagnosis of diseases in the early stages. SUBSTANCE: the mammograph has a source of X-radiation based on an X-ray tube, a system of X-ray polycapillar collimating optics-compression unit, a position - sensitive radiation detector of radiation passed through the gland tissue, a scanning unit for synchronous displacement of the mechanically linked radiation source and radiation detector, a system of arrangement of composite gland image according to the results of scanning, and a system of processing and visualization of the composite gland image. The inlet of the X-ray polycapillar collimating optics is focused on the actual focal spot of the source X-ray tube and has a profile similar to the focal spot, and the outlet is directed to the inlet port of the position-sensitive radiation detector and has a profile corresponding to the profile of the inlet port. EFFECT: improved quality of image consisting in improved spatial resolution, enhanced contrast sensitivity, and reduced distortions without any increase of the dose of radiation of the patient. 1 cl, 1 dwg

Description

 The invention relates to devices for radio diagnostics with scanning a test object with a narrow beam of x-ray radiation and digital recording of scan results, obtaining a composite image and visualizing it on a monitor screen. Due to the achieved spatial resolution with high sensitivity in contrast and a reduced radiation dose, the device can be used in mammography to determine the position of small non-palpable lesions of the breast that differ in density and to diagnose diseases that can be cured in the early stages.

 Currently, mammographs are used for the radiological diagnosis of breast diseases with the registration of x-ray images on film, and with electronic digital registration.

In the study of the mammary gland in systems with films [1], x-ray radiation penetrating the mammary gland falls on the phosphorescent screen. The light emitted from the screen is detected by a light-sensitive film, which is specially designed for the size of the breast and can be shown on the projector after development. The following disadvantages of devices with films are significant:
- graininess and noise of films limiting spatial resolution;
- loss of contrast in a single exposure of the breast to obtain its full image due to registration along with a useful signal of scattered radiation;
- increasing the patient's radiation dose when using films with higher resolution and using nets to protect against scattered radiation.

 More advanced mammographs are known [2] with electronic digital recording of X-ray images, in which instead of a film with a phosphorescent screen, a position-sensitive radiation detector that generates an electronic signal is used, which can be processed digitally and displayed on a monitor screen with high resolution in almost real time.

 The disadvantage of this device is the limited field of view of a positionally sensitive detector, as a result of which, with a high resolution, an image of only a small area of the breast can be obtained. With a single exposure of the entire mammary gland to obtain its full image, as in mammograms with a film, the contrast is lost due to registration with the useful signal of scattered radiation, and the introduction of additional nets to protect against scattered radiation leads to an increase in the patient's radiation dose.

The closest technical solution to the proposed is a digital scanning device for mammography [3], which contains:
- an x-ray source based on an x-ray tube,
- X-ray filtering system,
- collimator-shaper narrow fan beam of radiation for scanning the patient’s breast,
- a compression unit for squeezing and limiting the mobility of the breast,
- a scanning unit for scanning and receiving a signal about the passage of radiation through the mammary gland,
- positionally sensitive receiver of radiation transmitted through the gland tissue,
- a digital composite image composition system, the input of which is connected to the output of a positionally sensitive radiation receiver,
- block synchronization of the movement of the scanning unit with the reading of information from the radiation receiver,
- a composite image processing and visualization system, the input of which is connected to the output of the composite image layout system.

 In this device, scanning a breast with a narrow x-ray beam reduces the fraction of scattered radiation at the input of a positionally sensitive radiation receiver, thereby improving the signal-to-noise ratio, increasing the sensitivity in contrast and spatial resolution.

 However, recording breast lesions at an early cure stage of the disease requires greater contrast, since the characteristics of x-ray absorption by these lesions are similar to those of the surrounding tissue and the differences are noticeable only for the soft component of the radiation, and with greater spatial resolution, due to the small damage.

The disadvantages of the prototype are:
- a beam fan created by a collimator to fit the size of the breast, which causes distortion distortions along the edges of the field of view and leaves a fraction of the scattered radiation, which reduces contrast sensitivity and spatial resolution;
- the use of part of the focal spot of the x-ray source, and not its entire area when the radiation is collimated into a fan beam, which leads to a loss in the efficiency of use of radiation;
- "fuzziness" of the spectral distribution of x-ray quanta when using filters (or the presence of an unfiltered "hard" component), which prevents the improvement of contrast.

 The technical result provided by the claimed invention is to improve image quality, which consists in improving spatial resolution, increasing sensitivity in contrast and reducing distortion without increasing the dose of the patient.

 The technical result is achieved by the fact that in a digital scanning mammograph containing an x-ray source based on an x-ray tube, a compression unit, a positionally sensitive receiver of radiation transmitted through the gland tissue, a scanning unit configured to synchronously move mechanically coupled radiation source and receiver, a digital system a composite image of the gland, one input of which is connected to the output of a positionally sensitive radiation receiver, and the second - with the synchronization output of the scanning unit, and the composite image processing and visualization system, the input of which is connected to the output of the digital composite image composition system of the gland, an X-ray polycapillary collimating optics system is connected to the x-ray source, the input sections of each capillary of which are focal spot oriented at some distance x-ray source tube, and their output sections form the profile of a quasi-parallel radiation beam corresponding to the input th window of a positionally sensitive radiation receiver.

 The essence of the invention lies in the fact that the device scans the mammary gland with a narrow quasiparallel beam of soft X-ray radiation, and the projection of the gland in the direction of incidence of the radiation is detected due to this with improved spatial resolution with an increased signal to noise ratio with a reduced dose of radiation to the patient moving synchronously with the source radiation by a position-sensitive receiver with a receiving area similar to the beam profile. An electronic digital image composition system during scanning of the breast with a narrow quasi-parallel beam of “soft” radiation composes its composite image with a higher contrast sensitivity, which is displayed by a high-resolution image processing and visualization system on the screen of a video monitoring device.

 The drawing shows a diagram of a digital scanning mammograph.

 The mammograph contains an x-ray source 1 based on an x-ray tube, a multicapillary collimating x-ray optics system 2, a compression unit 3 for limiting the mobility of the mammary gland 4 of the patient, a positionally sensitive radiation receiver 5, a scanning unit 6 for simultaneously moving the radiation source 1 with a multicapillary collimating x-ray optics system 2 and a radiation receiver 5, a system 7 for arranging a composite image of the gland according to the results of scanning, and a processing system 8 and and imaging prostate composite image.

 A system of x-ray polycapillary collimating optics 2 is connected to the x-ray source 1 on the basis of the x-ray tube, the input of which is oriented to the actual focal spot of the x-ray tube of the source and has a profile similar to the focal spot, and the output is directed to the input window of the positionally sensitive radiation receiver 5 and has a profile, corresponding to the input window. The system of x-ray multicapillary collimating optics 2 consists of a large number (several thousand per square centimeter) of capillary channels with a high transparency coefficient (up to 70%), oriented so that the input sections of each capillary of the system at some distance converge into some virtual focal spot, compatible with the focal spot of the x-ray tube of the source, and the output sections of the capillaries of the system are directed to the input window of the positionally sensitive radiation receiver 5, forming the corresponding Give him the profile of a quasi-parallel radiation beam generated by system 2. The material and size of the capillaries and their permissible bending are selected for the limiting angles of total external reflection corresponding to the range of quantum energies 15 - 21 keV. The positionally sensitive radiation detector 5 is located behind the compression unit 3 and is a line of charge-coupled devices (a line of CCDs) with a common fiber-optic input window covered with a scintillator. The output of the CCD array of positionally sensitive radiation detector 5 is connected to the input of the composite image layout system 7. A radiation source 1 with a system of x-ray multicapillary collimating optics 2 and a radiation receiver 5 are rigidly interconnected by a scanning unit 6, which ensures their mechanical movement and generates synchronization signals. The synchronization output of the scanning unit 6 is connected to the input of the composite image composition system 7, the output of which is connected to the input of the image processing and visualization system 8, made on the basis of a PC computer and a VKU video monitoring device. The composite image composition system 7 is made using the methods and elemental base of digital technology - a processor, an analog-to-digital converter, amplifiers, and an interface for exchanging information with a PC computer and a video control device of the VKU of image processing and visualization system 8.

 The device operates as follows.

 The radiation from the focal spot of the x-ray tube of the radiation source 1 enters as a sliding beam at the input of the x-ray multicapillary collimating optics system 2. Due to multiple total external reflection, only soft radiation quanta pass through the output, which are narrow quasi-parallel beam, the profile of which is determined by the placement of capillaries at the output of system 2 penetrate through the mammary gland 4, fixed by the compression unit 3, and fall on the input window of the radiation receiver 5. Passed through the mammary gland 4 zluchenie scintillator in the receiver input window 5 is converted into light, which range from the CCD converts the charge, and then the output of the CCD device - into a voltage. The CCD operates in a time delay and accumulation mode, in which the charge in the CCD moves synchronously with the mechanical movement of the radiation detector 5 and radiation source 1 with a system of X-ray multicapillary collimating optics 2 according to the signal from the scanning unit 6. When the radiation receiver 5 and the source 1 s are mechanically moved system 2 at a distance equal to one scanning element, the charge in the CCD is also shifted by one element. Of the scanning elements in the system 7, a composite image is composed, which, after processing in the system 8, can be displayed on the screen of the video monitoring device of the VKU.

In the proposed device, unlike the prototype, for scanning, not a fan beam is formed, which introduces distortion distortions and scattered radiation, which reduces contrast sensitivity and spatial resolution, but a quasi-parallel narrow beam. A narrow quasi-parallel beam of “soft” radiation from a source based on an X-ray tube with a finite focal spot size is formed using a system of X-ray multicapillary collimating optics based on the effect of total external reflection of radiation from the inner surface of the walls of the capillaries. As a result, the total angle of rotation of the x-ray radiation captured from the diverging non-point x-ray source is determined by the bend and cross section of the channels of the capillaries and can far exceed the critical angle of total external reflection θ (for glass, θ = 30 / E radian). The critical angle value depends on the radiation energy, composition, density and surface quality of the inner walls of the capillary. The system of multicapillary x-ray collimating optics in a mammograph is also used as a filter to suppress the high-energy part of x-ray radiation, since the radiation intensity is weakened by at least an order of magnitude outside the operating wavelength range. The achieved limitation of the spectral composition of the scanning radiation due to a decrease in the fraction of high-energy quanta increases the sensitivity of recording by contrast in soft tissue. The divergence of the X-ray photon beam that is of the order of 10 ⁻³ rad in the energy range (15–21) keV, which can be expected, allows one to expect a spatial resolution of ~ 20 lines / mm. With the same spatial resolution in the proposed device when forming the beam profile, the entire area of the focal spot of the source x-ray tube is used, and not part of it, as in the collimation in the prototype, which allows the use of traditional x-ray sources with an extended focal spot and low specific power. An indisputable advantage is the invariable divergence of the order of 10 ⁻³ rad over the cross section of the beam of x-ray quanta at the output of the x-ray multicapillary collimating optics system. The contrast sensitivity of the proposed device is higher, since the system of x-ray polycapillary collimating optics does not pass the hard component of the spectrum and there is no blurriness introduced by the filtering system of the prototype.

 Thus, in the proposed device, in comparison with the prototype, the image quality is improved due to improved spatial resolution, increased sensitivity by contrast and reduced distortion distortion.

Sources of information
1. US patent N 4998270 3/1991 Scheid et al. 378/37.

 2. US patent N 5844242 12/1998 Jalink Jr. et al.

 3. US patent N 5526394 6/1996 Siczek B. et al. (prototype).

Claims (1)

 A digital scanning mammograph containing an x-ray source based on an x-ray tube, a compression unit, a position-sensitive receiver of radiation transmitted through the gland tissue, a scanning unit configured to synchronously move mechanically coupled radiation source and receiver, a digital composite image composition system of the gland, one the input of which is connected with the output of the position-sensitive radiation receiver, and the other with the synchronization output of the scanning aggregate a, and the processing and visualization system of the composite image of the gland, the input of which is connected to the output of the digital composite image composition system, characterized in that the system of x-ray polycapillary collimating optics is connected to the x-ray source, the capillary channels of which are oriented so that they can be combined at a certain distance input sections with the focal spot of the source x-ray tube, and their output sections form the profile of a quasi-parallel radiation beam corresponding to the profile of the input window of a position-sensitive radiation receiver.