RU2086177C1 - Method for diagnosis of surfaces of bioobjects with use of reflected radiant energy - Google Patents

Abstract

FIELD: medical equipment. SUBSTANCE: method is based on formation of the image of the focus of pathology or affection according to the intensity of reflected energy and determination of the focus characteristics according to the obtained image. The obtained site of the pathology focus is divided into several non-interlaced closed side by side; the image of each of them is presented in accordance with the value of a definite, for example mean quantity of intensity of reflected energy for the given site, in particular, by imparting a definite color tint to this site; absorbability of the object of examination is judged by the obtained distribution of intensity. EFFECT: enhanced accuracy of determination of absorbability of the sites of the bioobject surface under examination by exclusion of errors due to glares on the image of the surface under examination. 4 dwg

Description

 The invention relates to medical diagnostics, and in particular, to methods for diagnosing surfaces of biological objects using images of the test surface obtained from reflected radiant energy, and can be used for biomedical and biophysical studies, as well as in various fields of practical medicine, in particular, dermatology, oncology, in the treatment of wounds in light massage to select treatment modes of biological tissue, for example, laser radiation, taking into account the absorption capacity of various ASTK tissue.

 A known method for the diagnosis of affected surfaces of biological objects using reflected radiant energy by obtaining by means of a camera image of the affected tissue to determine the position of the affected area from the received image (Pat. UK N 2126717, G 1 A, 1982, as well as "The use of lasers for the diagnosis of diseases [ according to the foreign press for 1968-1986, G. A. Simonov, P. G. Schwalb, "Reviews on electronic technology. Ser. 11. Laser technology. and optoelectronic.", issue 7 (1300) , M. Central Research Institute "Electronics", 1987, p. 14-16).

 The disadvantages of this method are the limitation of its functionality only by determining the shape and location of the affected area, the inability to adjust the television image.

 There is also a method of diagnosing surfaces of biological objects using reflected radiant energy by obtaining images of tissues using a computing device and determining their state from the resulting image ("The use of lasers in medicine [according to domestic and foreign press for 1971-1985", M .T.Alexandrov et al. "Surveys of the electronic tech. Ser. 11. Laser. Tech. And optoelectron.", Issue 9 (1228), M. Central Research Institute "Electronics", 1987, p. 18-20).

 The disadvantage of this method is the reduced accuracy of diagnosis of superficial skin lesions due to the influence of glare on image quality. The cause of glare is the scattering of laser radiation on the irregularities of the investigated surface. The presence of glare in the image leads to distortion in the corresponding places of the image of the true intensity of the reflected signal, which is the desired useful informative characteristic of the signal. In places of glare, the image provides incorrect information about the degree of reflection of the radiant energy of the tissue's absorption capacity. Given the erroneous knowledge of absorption capacity, in particular, an incorrect conclusion can be made about the radiation dose required for such areas, which will lead to inaccessible or ineffective exposure to radiation.

 There is also known a method for diagnosing biological objects using reflected radiant energy by obtaining, using a computing device, an enlarged image of the studied biological material (blood plasma), forming in the image at least one closed area corresponding to the outline of the object of study (the shape of each of the blood cells), and determining the resulting image of the characteristics of the studied material (number of bodies) ("Computer-controlled laser microscope irradiation system", "The Review of Laser Engineering ", 1987, 15, No. 3, pp. 20-28, Japanese rez. English).

 When using this method for the diagnosis of superficial skin formations, its disadvantage is also the effect of glare, distorting the distribution pattern of the intensity of the reflected signal.

 In addition, there is a known method of obtaining through a computer in the color image mode the equivalent fields of an x-ray by double processing on an analog computer and intermediate photographing (ed. St. USSR N 1627131, class A 61 B 6/00, 1985).

 The use of this method for processing the image of an affected or pathological skin surface obtained using reflected radiant energy does not allow to get rid of glare in the image and complicates the intensity distribution pattern, if any, which limits the scope of the method.

 Closest to the proposed one is a method for diagnosing pathological formations using reflected radiant energy by forming the intensity of the reflected energy of the image of the lesion of the pathology or lesion and determining from the received image the required characteristics of the lesion, namely its shape and size (ed. St. USSR N 1543615, class A 61 N 5/06, 1987).

 The disadvantage of the prototype method is the reduced accuracy of determining the absorption ability of a pathological formation or other kind of affected surface due to the effect of image glare on the image quality, which leads to a distortion in the intensity distribution of the reflected signal, which is a useful informative characteristic and testifies to and absorption capacity of areas of the tissue under study.

 The objective of the invention is to increase the accuracy of determining the absorption capacity of various sections of the studied tissue of a biological object by eliminating errors due to glare in the image.

 To solve the problem in the known method for diagnosing surfaces of biological objects using reflected radiant energy by forming the intensity of the reflected energy of the image of the lesion pathology or lesion and determining the lesion characteristics from the received image, the obtained lesion region is divided into several additional and / or adjacent additional disjoint closed areas, the image of each of which is represented in accordance with a certain value, for example p, the average value of the intensity of the reflected energy for this region, in particular, by giving this region a certain color shade, and according to the obtained intensity distribution, the absorption ability of the object under study is judged.

 Introduction to the prototype method of new distinctive operations, the selection in the image of the studied area of the biological object of several additional areas and the presentation of the image of each of them in accordance with a certain value of the intensity of the reflected energy, which are, in particular, average for this additional area, provides in combination with the limiting features of the method image acquisition of the studied object without magnified in its individual areas due to glare of the intensity values of the reflected energy. This is a new technical result obtained in the implementation of the proposed new technical solution.

 The above increases the effectiveness of diagnosis and subsequent treatment of skin lesions.

In FIG. 1 shows a structural diagram of an installation for implementing the proposed method; in FIG. 2 is a graph of the reflection coefficient during one of the passes of the beam along the studied area of the biological object, a solid line, and a step curve of the reflection coefficient (dashed line) established by the researcher or operator; in FIG. 3 version of the image of the studied area of the biological object with one additional area (D) of the extreme value of the reflection coefficient; in FIG. 4 version of the image of the studied area of the biological object with two additional areas (G and G) of extreme values of reflection coefficients;
In FIG. 3 and 4, the following notation is accepted:
A, B, C, D, D, E and F additional areas of the investigated biological object;
K is the value of the reflection coefficient equal to the ratio of the power reflected from the object to the incident on it, rel. units

 L spatial coordinate, see

 Installation for implementing the method (Fig. 1) contains a radiation source 1, for example, a laser with a beam 2, a partially reflecting mirror 3, a mirror 4 with a central hole, movable, rotating relative to two mutually perpendicular axes, a mirror 6 of the device 7 for moving the beam over surface 8 bioobject, a direct signal power sensor 9 and a reflected signal power sensor 10. The installation also contains a computing device, including a processor 11 with a memory connected to the display 12 and the processor control unit 13 (keyboard, mouse device). The inputs 14, 15 of the processor 11 are connected to the outputs of the sensors 9, 10, the output 16 of the processor is connected to the input of the beam movement control device 7.

 As a radiation source 1, for example, a helium-neon laser can be used, as a computing device of a personal computer of the IBM PC / AT type with corresponding software. As sensors 9 and 10, photosensors of the FD-256 type are used. As a software tool, an image processing program is used, for example, of the IMAGE type (NPO Spektr, Moscow).

 The installation operates as follows.

 When the laser 1 is on, beam 2 first hits the mirror 3. A known smaller part of the power of beam 2 is reflected from the mirror 3 and gets to the direct-power photo-sensor 9. Most of the power passes through the mirror 3, then through the hole 5 in the mirror 4 and enters the mirror 6 of the beam moving device 7, controlled by the program from the processor 11. The direct laser beam is reflected from the mirror 6 installed at a given angle and sent to the desired point of the studied surface 8 of the bioobject. The signal 17 reflected from the surface of the biological object is reflected from the mirrors 6 and 4 and enters the sensor 10 of the reflected signal power. Using the appropriate software using the signals from the sensors 9 and 10 in the processor 11, the coefficient K of the reflection of power from the surface 8 of the biological object is calculated. On the display screen 12, an image of the studied point of the surface of the object is formed. The image of the point can be reflected on the screen, for example, with the intensity of the set color proportional to the calculated value of the reflection coefficient. Or the image can be given a certain color depending on the range of values in which the calculated value of the reflection coefficient is located. The obtained values of the coefficients for all points of the image are recorded in the memory of the PC.

 When beam 2 of laser 1 passes around the studied surface 8 of a biological object, an image of this surface is formed on the display screen in the selected color (or in black and white), the distribution of the degree of saturation (brightness) of which over the image represents a picture of the distribution of the reflection coefficient over the surface of the studied area of the object, including interference changes in reflection coefficient due to glare. In FIG. Figure 2 shows an example of the distribution of the reflection coefficient for one of the passes of beam 2 over the studied region (solid line 18). Peaks 19 correspond to reflections due to flare.

 The resulting image can be edited using an image processing program. By setting a certain value of the reflection coefficient, it is possible to create an image of the line as a set of points with a given value of K. In particular, the affected area of the surface under study is thus distinguished by the boundary value of the reflection coefficient (closed curve 20 in Figs. 3, 4). For several given values of K, a set of lines can be obtained that breaks down the object of study into several additional areas A, B, C, D, D, F (Figs. 3, 4). Here, for example, regions B, C and D are nested one into another, regions C and D are next to each other.

 The boundaries of the regions are edited in order to include images of glare in one or another additional region or to highlight the desired area of the affected surface of the biological object. The obtained additional image areas can be highlighted by giving each of them, for example, color intensity (not shown in the drawings), corresponding, for example, to the value of the reflection coefficient previously selected for one of the curved lines limiting this region. At the same time, their images disappear interfering bright places corresponding to glare. This is illustrated by stepped line 21 in FIG. 2, sections 22 and 23 of which correspond to additional areas of the edited image, which now have constant intensity values for these areas without glare emissions.

 An additional region can also be distinguished by the color intensity corresponding to the average value of the reflection coefficient for this region, obtained as the arithmetic mean of the values of the intensity coefficients of the curves that bound the region.

 The method operates as follows.

 By sequentially passing the beam 2 using the device 7 of the surface 8 of the investigated biological object while measuring the reflection coefficient on the display screen 12, an image of the studied surface of the biological object is constructed, reflecting the distribution of the reflection coefficient over it, which characterizes the absorption capacity of the surface. The maximum and minimum values of the reflection coefficients obtained by the processor are determined and the boundary value of the reflection coefficient for the affected area is set equal to the coefficient value for a normal, non-affected surface. Using a boundary value for the affected surface of the reflection coefficient, a curve is built on the screen that separates the affected part of the surface from the normal one, highlighting the affected area. If necessary, the region is refined by selecting the boundary value of the reflection coefficient and comparing the resulting contours of the region with the object under study, as well as by manually correcting the region's contour.

 By setting a series of values of the reflection coefficient that are in the range from minimum to maximum, several curves corresponding to these values are constructed, forming closed, adjacent, or adjacent to each other additional areas of the object of study (for example, area A-G in Figs. 3, 4). The choice of the number of these values of the coefficients, that is, the number of additional areas, is carried out, in particular, inversely with the magnitude of the gradient of the reflection coefficient in the resulting image. The shape of the additional areas is determined by the distribution of the measured values of the reflection coefficient over the image. The number and configuration of additional areas and the values of reflection coefficients assigned to them are adjusted in accordance with the location of the glare to eliminate their influence, as well as in accordance with the need to highlight for an expert assessment of one or another part of the studied surface of the biological object. Partial highlighting of additional areas can only be done for areas of the image that have glare.

 The image of each of the additional areas is given the intensity of the selected color corresponding to, for example, the above average value for this area. To represent images of additional areas, intensities (shades) of gray or a color approaching the color of the test surface, such as brown, are used.

 The result is an image of the studied affected area of the object, devoid of glare and divided into areas subject to individual analysis (corresponding to additional areas of the image). The color intensity of each of the plots reflects the value of its absorption capacity, and the ratio of the color intensities of the plots to their relative absorption capacity.

 According to the received image of the studied pathological area with the selected researcher, in accordance with its condition, the surface areas conduct an individual and comparative assessment of the absorption capacity of these areas, taking into account the degree of damage to each area, the general condition of the examined area of the bioobject. The evaluation results are entered into the PC and entered into the database for subsequent use in research or treatment.

 For the treatment of each of the additional areas, a specific radiation dose is prescribed, the sum of which will be equal to the total radiation dose required for the affected area. The image of the study area and the obtained values of radiation doses assigned for additional areas are also entered into the database. The result of the method in this case is the obtained physical representation of the dose field, which is then used to form the dose field when the affected area is irradiated, for example, by a laser beam.

Claims (1)

A method for diagnosing surfaces of biological objects using reflected radiant energy by generating, using a software computing device, the intensity of the reflected energy of a visual physical representation of the test surface on an appropriate storage medium
a display screen with highlighting on the resulting image several separate geometrical places of points with a given constant value of the reflection coefficient and determining the characteristics of the object from the received image, characterized in that each of the geometrical places of the points is formed in the form of a closed two-dimensional area that does not intersect with the others by assigning each area its own reflection coefficient values and displaying this reflection coefficient value by giving a given region a certain color or ttenka color, and in the resulting image are judged on the absorption capacity of the object.

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