RU2347524C1 - Method for diagnostics of maxillofacial area pathology - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: light is serially sent to unaffected and affected surface, reflected light is collected, then sent to spectrum analyser, and colorimetric treatment of reflection spectra is carried out. Investigated surfaces are additionally illuminated with ultraviolet light, fluorescence light is collected and sent to spectrum analyser, colorimetric treatment of fluorescence spectra is carried out, compared to appropriate colorimetric characteristics of surface in white and ultraviolet light in normal condition, if characteristics coincide, normal condition is diagnosed, if deviations are registered, conclusion is drawn on availability of pathology that requires therapeutical correction; comparison is carried out minimum by four colour coordinates of reflection spectra and fluorescence spectra.

EFFECT: higher accuracy and validity of maxillofacial area pathology diagnostics.

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Description

The invention relates to medical diagnostics and can be used for biomedical research in dentistry, dermatology, oncology, facial surgery, in particular for determining the condition of bone tissue, mucous membranes, skin integuments.

The prior art method for measuring the photoluminescence of biological tissues [and.with. USSR №1800897, class G01N 33/48, 1989].

The method is as follows. The test tissue is illuminated with white light that does not contain wavelengths corresponding to its photoluminescence band in its spectral composition. Observation in white light and registration of its photoluminescence is carried out simultaneously using a special device. The method is used for endoscopic examination.

The method is characterized by low accuracy in estimating the color of the fluorescence of an object. It is subjective, since the assessment of the qualitative indicators of color depends on the physiological characteristics of the observer’s vision, his experience of colorimetric observations, as well as the conditions of observation and comparison. The disadvantages of the method include the fact that it can be used only in conditions of endoscopic fluorescence diagnostics, since a special device claimed by the authors is an interference filter placed on the eyepiece of the endoscope.

A known method for the diagnosis of surfaces of biological objects using reflected radiant energy by forming using a software computing device by the intensity of the reflected energy a visual physical representation of the investigated surface on an appropriate storage medium - display screen [RF patent No. 2086177, from 10.08.97, cl. A61B 6/00, 1992]. On the resulting image, several separate geometrical places of points with a given constant value of the reflection coefficient are distinguished. Then, each of the geometrical places of the points is formed in the form of a closed, non-intersecting with another two-dimensional region of its predetermined reflection coefficient and the value of this reflection coefficient is displayed by giving this region a certain color or color cast. An individual and comparative assessment of the absorption capacity of these areas is carried out according to the image of the studied pathological area with the researcher selected in accordance with its condition, taking into account which the degree of damage to each area and the general condition of the examined area of the biological object are evaluated. The evaluation results are entered into a personal computer and entered into the database for subsequent use.

Also known is a method for the diagnosis of bioobjects [RF patent No. 2106802, from 03.20.98, cl. A61B 6/00, 1992], which includes the formation on a display using a computer of images of the object of study, the light characteristic of each point of which reflects the state of the corresponding point of the object, with subsequent determination of its characteristics. Moreover, the images obtained during various examination sessions are shown on the display sequentially one after another with the transfer of one image to another in accordance with the chosen law of change in the light characteristics of the coincident points of successive images.

In the implementation of the above methods, the intensity of the reflected energy from the surface of the object of study is used to obtain a reflection coefficient by which the presence of the affected area is judged.

The disadvantages of the methods [RF patent No. 2086177, class. A61B 6/00, 1992 and RF patent No. 2106802, class. A61B 6/00, 1992] can be attributed the limitation of the assessment of the absorption capacity of a surface only by the reflection coefficient of this surface at the wavelength of the irradiating laser. In addition, the first method is time-consuming, since the boundaries of the pathological region are clarified 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. This introduces a subjective error in the final result.

Closest to the technical nature (prototype) is a method for evaluating the color of tooth restoration [RF patent No. 2268656, from 01.27.2006, class. A61B 10/00, 2006].

The method consists in the fact that the supply of light to the unaffected area of the tooth and the collection of reflected light is carried out by means of a photometric ball. The reflected light is sent to a spectrum analyzer, where the chromaticity coordinates are determined from the reflection spectrum, compared with the known chromaticity coordinates of the samples of the filling material and, if the color difference does not exceed 2-3 thresholds, then the filling material is selected, and if the color difference is greater than indicated, then choose two filling materials, lay them on top of each other and add a third to reduce the color difference to the specified limit, carry out a control determination of the color coordinates of the seal, and with In case of confluence with the chromaticity coordinates of the unaffected tooth section, not exceeding 2-3 thresholds, the color estimate is considered identical. Moreover, the method provides that the chromaticity coordinates of the seal are determined by applying light to it and collecting reflected light by means of a photometric ball and performing colorimetric processing of its spectrum.

The disadvantage of this method is its limited only one task - the assessment of the therapeutic effect of tooth restoration for the selection of filling material.

The disadvantage of all of the above methods for assessing the state of dental objects is their intended use for the analysis of only one pathological condition.

Pathology of the maxillofacial region is associated with a change in the color of the investigated surface. This is due to the superficial location of a large number of blood vessels and, as a result, a violation of the blood supply to the object during the disease [1, 2, 3, 4]. Moreover, almost all pathological processes in biological tissues have fluorescence characteristics that differ from those in the norm [1, 2].

Diagnosis of such diseases is associated with solving the colorimetric problem of distinguishing surface color and surface fluorescence color in pathology and is normal.

An object of the invention is to increase the accuracy and reliability of the diagnosis of pathology of the maxillofacial region, improving differential diagnosis.

The technical result is achieved by supplying illuminating light through a fiber for input to an unaffected and affected surface in series, collecting reflected light and directing reflected light to a spectrum analyzer for subsequent colorimetric processing of the reflection spectrum. According to the invention, the affected surface is additionally illuminated with ultraviolet light, fluorescence light is collected and sent to a spectrum analyzer for subsequent colorimetric processing of the fluorescence spectrum. Diagnostics is carried out by comparing the colorimetric characteristics of the unaffected and affected surface in white light and ultraviolet light. The colorimetric characteristics of a surface that does not have signs of disease are taken as the norm, if the characteristics coincide, the norm is diagnosed, when deviations are registered, a conclusion is made about the presence of a pathology that requires therapeutic correction.

The proposed method can be implemented, for example, using a special device that allows you to illuminate the affected surface with white light (source type "A"), collect the reflected light and direct it to the spectrum analyzer. Then illuminate the affected surface with ultraviolet light, collect the fluorescence light and direct it to the spectrum analyzer. The same operations must be carried out for a surface that does not have signs of disease.

To obtain colorimetric characteristics, a device that can be used to implement the method should include a processing unit, which is an electronic computer with a specially developed algorithm for processing signals from a spectrum analyzer. The algorithm provides that colorimetric processing is carried out by the method of weighted ordinates [5] and includes the calculation of color coordinates and color coordinates in accordance with the recommendations of the International Commission on Lighting [6].

In addition, it is advisable to invest in the algorithm of the electronic computer the operation of recalculating the chromaticity coordinates in the coordinates of an equal-contrast system, in which the distance between the points corresponds to the degree of color difference between the colors represented by these points. Moreover, the two colors practically do not differ if the coordinates are separated by no more than 3 thresholds, differ uncertainly if they are no more than 5 thresholds, and confidently differ with an interval of 9 thresholds or higher [5].

An additional technical result is ensured by the fact that the received reflection signals and fluorescence signals can be used to obtain an integrated reflection coefficient, calculation of color differences, color tone and saturation, which eliminates subjectivity in the diagnosis of diseases.

The proposed method for the diagnosis of dental objects of the maxillofacial region allows to provide an absolute measurement error at the level of 0.005 color coordinate units for colorimetric measurements, which ensures the accuracy of colorimetric estimates at the level of no more than 3 thresholds [7].

Example 1

Patient M., aged 45, came to the reception with complaints of discomfort and a feeling of roughness in the tongue.

On examination, it was found - on the edematous surface of the tongue there are papules that tend to merge.

Measurements were made of surface color and surface fluorescence color. To do this, we measured the reflection spectrum and the fluorescence spectrum on the unaffected surface of the tongue mucosa, and then performed the same manipulations on the affected surface. After colorimetric processing of the spectra, the following results were obtained:

Table 1 The results of colorimetric processing of the pathology zone of the areas of the oral cavity of patient M. Localization Unaffected surface Affected surface Visual inspection surface color Pale red Burgundy red (hyperemia) Color coordinates x = 0.513; y = 0.271 x = 0.616; y = 0.301 Visual fluorescence color Orange color Whitish glow Color coordinates x = 0.581; y = 0.411 x = 0.367; y = 0.392

Thus, in this clinical case, the diagnosis is made: lichen planus, exudative-hyperemic form. Treatment is carried out to a state in which the chromaticity coordinates of the affected surface will differ from the chromaticity coordinates of the unaffected surface not more than 3 thresholds.

Example 2

Patient V., 48 years old, complained of discomfort when eating.

On examination, it was found - on the lateral surface of the tongue on the right, as well as in the corners of the mouth, there are white spots with clear boundaries.

Measurements were made of surface color and surface fluorescence color. To do this, we measured the reflection spectrum and the fluorescence spectrum on the unaffected surface of the tongue mucosa, and then performed the same manipulations on the affected surface for the same purpose. After colorimetric processing of the spectra, the results obtained are presented in Table 2.

table 2 The results of colorimetric processing of the pathology zone of the oral cavity of patient B. Localization Unaffected
surface Stricken
surface Visual inspection surface color Pale red Burgundy red (hyperemia) Color coordinates x = 0.514; y = 0.321 x = 0.464; y = 0.430 Visual fluorescence color Orange color (tongue surface), red (in the corners of the mouth) Bright blue glow Color coordinates x = 0.586; y = 0.407
(surface of the tongue);
x = 0.579; y = 0.341
(in the corners of the mouth) x = 0.201; y = 0.356

In this clinical case, comparing the clinical symptoms and using the developed method, we make the diagnosis: leukoplakia is flat. We carry out the treatment to a state in which the chromaticity coordinates of the affected surface will differ from the chromaticity coordinates of the unaffected surface by no more than 3 thresholds.

Example 3

Patient M., 27 years old, has a deep carious cavity in tooth 21 on the proximal-medial surface with a grasp of the cutting edge. The tooth is in the smile zone and, therefore, the filling material should have colorimetric characteristics in white and ultraviolet light similar to the colorimetric characteristics of the tooth.

For each localization point of the unaffected tooth area — the cutting edge, body and cervical region, measurements were performed in white and ultraviolet light, followed by colorimetric processing. The results are shown in table 3. According to the obtained reflection spectra and fluorescence spectra of the tooth, it was proposed to use the restoration materials shown in table 3 for filling.

Table 3 Comparative spectral characteristics of restoration materials Localization Cutting edge Tooth body The cervical region Coordinates x = 0.422 x = 0.422 x = 0.429 Color y = 0.418 y = 0.423 y = 0.429 Coordinates x = 0.242 x = 0.243 x = 0.249 Fluorescence y = 0.358 y = 0.353 y = 0.359 Proposed Restoration Materials C ₁
(Spectrum TPH) + shade I OA ₂
(Spectrum TPH), V ₂ (Spectrum TPH) + shade I OA _3.5
(Spectrum TPH), B ₃ (Spectrum TPH) + shade I The color difference between the color of the fill and the color of a healthy tooth (color threshold) 3 2 3

After the filling operation, control measurements of the color of the filling were carried out in white and ultraviolet light at the points of localization - the cutting edge, body and cervical region. The color difference in all cases does not exceed three thresholds, from which we conclude that the color of the filling material is selected correctly.

Bibliography

1. Diseases of the oral mucosa: Textbook / Ed. L.M. Lukins. - N. Novgorod: Publishing house of the NGMI. 1993 .-- 212 p.

2. Therapeutic dentistry: Textbook / Ed. prof. L.A. Dmitrieva. - M .: MEDpress-inform, 2003 .-- 896 p.

3. Therapeutic dentistry: Textbook for medical students / Ed. E.V. Borovsky. - M.: “Medical News Agency”, 2003. - 840 p.

4. Lutskaya I.K. Dentistry Guide. - Rostov-on-Don: “Phoenix”, 2002. - 540 p.

5. D. Judd, G. Wyshecki. Color in science and technology. Per. from English - M .: Mir, 1978.- 513 p.

6. International Commission on Illumination - (www.cie.co.at/cie).

7. Krivosheev M.I., Kustarev A.K. Color measurements. - M .: Energoatomizdat, 1990 .-- 240 p.

Claims (1)

A method for the diagnosis of pathology of the maxillofacial region, including the sequential supply of light to an unaffected and affected surface, collecting reflected light, directing it to a spectrum analyzer and colorimetric processing of the reflection spectra, characterized in that the surfaces under investigation are additionally illuminated with ultraviolet light, the fluorescence light is collected and sent to spectrum analyzer, colorimetric processing of fluorescence spectra is carried out, compared with the corresponding colorimetric characteristics and surfaces in white and ultraviolet light of a similar unaffected area, if the characteristics coincide, the norm is diagnosed, when deviations are registered, a conclusion is made about the presence of a pathology that requires therapeutic correction; a comparison is carried out with at least four color coordinates of the reflection spectra and fluorescence spectra.