RU2202280C1 - Method for determining human being age from morphometric parameters of histological bone tissue preparations - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves measuring morphometric parameters of histological bone tissue preparations like longitudinal and transverse slices of the III rib, transverse slices of tibial epiphysis and diaphysis, measuring ratios between cartilage and bone tissue areas in transitional zone of the rib, extent of active osteogenesis zone, endotrabecular osteon Gavers canal diameter, the number of endotrabecular osteons. The results are input into regression equations and human age is obtained by means of calculation. EFFECT: high accuracy in determining dead person age. _

Description

 The invention relates to forensic medicine, and in particular to methods of forensic identification of a person. It is designed to determine the age of a person by morphometric parameters of histological preparations of bone tissue.

 In forensic practice, the determination of a person’s age is carried out mainly with the aim of establishing an identity. If it is impossible to determine age by macroscopic features, which is typical for cases of late cadaveric changes, damage, dismemberment and skeletonization of corpses, a morphometric study of histological preparations of bone tissue as the least susceptible to destruction can be used.

 As you know, in the course of an individual’s life, the structure of his bone tissue is constantly being rebuilt under the influence of changing mechanical stress, changes in mineral metabolism in the body and the need for regeneration of bone tissue due to the wear of its structural elements. Traces of repeated cycles of adjustment are preserved in the microstructure of the bones, and the degree of its changes depends on the number of these cycles that managed to occur in the studied anatomical region during the individual’s life. This dependence is based on the method of quantitative study of histological signs of age-related restructuring and determination of age by the severity of these signs.

 A method for determining age based on counting the number of different microscopic elements of bone tissue was first proposed by Kerley E.P. in 1965. Later, many researchers worked on improving this method in order to increase its accuracy. In particular, in our country in 1965, Yu.M. Gladyshev created the original classification of osteons and osteon systems [3], which was used by V.F. Mordasov [5] to develop criteria for determining age by the number of osteon structures of various types, calculated in bone tissue preparations. However, recent studies have shown that this method has a significant drawback consisting in the difficulty of differentiating different forms of osteons and other studied elements, the result of which is the inaccuracy of their calculation and, accordingly, the unreliability of the results [10]. Therefore, there was a need to use such microscopic structures of bone tissue, which can be unambiguously and reliably determined by a practical histologist. In addition, there is a previously unrealized opportunity to improve the accuracy of diagnosing a person’s age by measuring the lengths and areas of these structures.

 To solve a similar problem, Nainis J.-V. [6] proposed a method for determining the age of a person with an accuracy of 5 years, based on histological and micro-x-ray diffraction studies of tissue samples from the femur and humerus. The criteria for determining age that he proposed were fairly simple and reliable, but the method had a significant drawback consisting in the rejection of a quantitative analysis of drugs and the use of only a qualitative description of them, which led to insufficient objectivity of the results [1, 2]. Nevertheless, the method of J.-V. Nainis, as well as V.F. Mordasov can be considered analogues of our invention.

 The closest prototype of the claimed invention was the work of Lozupone E. et Favia A. [9], in which for the first time in forensic practice an attempt was made to use a fundamentally new set of parameters for determining age, in particular, characterizing trabecular bone tissue. However, the number of parameters studied by the authors of the cited work was insufficient to develop on their basis a model for determining age suitable for practical use.

 In addition, it is generally accepted that the most difficult time for determining age is the period from 18 to 50 years, when bone growth is almost complete, and the expressed manifestations of age-related involution have not yet begun. All the techniques of the above authors allow us to determine the age in this period with minimal accuracy, since optimal morphometric parameters have not yet been found by measuring which this accuracy could be significantly increased.

 In this regard, we were tasked with finding the optimal morphometric parameters necessary for accurate determination of age in this range (18-50 years), and developing a comprehensive effective way to determine a person’s age using morphometric parameters of histological bone tissue preparations.

 In accordance with the literature, according to which the use of two or more bones gives more accurate results than the study of a single bone [11], two objects of study were selected. The basis for the selection of the tibia was the experience of identification work during the mass deaths of people in the zone of local military conflict, during which it turned out that under these conditions, the tibia is better preserved than others. The rib was used as the second object of research, since all processes in bone tissue, including age-related rearrangement, are most pronounced precisely at the border of the bone and cartilage of the rib [7].

 The initial set of measured parameters included 39 signs and was developed on the basis of literature data and the results of our own studies of age-related changes in bone tissue. A database was created containing quantitative descriptions of histological preparations made from bone samples of persons of a known age.

 As a result of statistical analysis, quantitative signs were selected that have the most pronounced dependence on age: the thickness of the cortical layer, the ratio of the areas of myeloid and adipose tissue in the bone marrow, the density of osteocytes, the ratio of the areas of cartilage and bone tissue in the transition zone, the length of the zone of active osteogenesis, havers diameter channels and the number of endotrabular osteons, the area of the trabeculae in the field of view, the thickness of the trabeculae, the diameter of the Haversian channels and osteons, the thickness of the layers of the outer and inner nney master plates, the overall density of osteons, osteons rearranged density with a central division and osteons, dark stained with Alizarin Red S, et al.).

 Qualitative features were also selected that allow identifying an identified individual to a specific age group before conducting quantitative measurements. These are signs such as the presence and severity of the layers of cartilage in the transition zone of the rib, the presence or absence of a growth line, the presence or absence of synostosis, the thickness of the bone trabeculae, the presence and number of endotrabular osteons, the thickness of the subchondral plate in the tibial epiphysis, the ratio of myeloid and adipose tissue in the bone marrow cavities of the rib.

 When analyzing the initial set of parameters, it was found that in the range from 18 to 30 years, the greatest correlation coefficients with age were for such signs as the ratio of the areas of cartilage and bone tissue and the length of the active osteogenesis zone in the transition zone of the longitudinal section of the rib. Measurement of the diameter of the Haversian canals of the endotrabecular osteons of the tibial epiphysis and counting of the endotrabecular osteons of the tibial diaphysis were most effective for a period of 27 to 50 years.

 Based on the selected set of quantitative parameters (see the list above), a complex of multidimensional regression models for determining a person’s age was developed and, thus, an integrated method for determining a person’s age by morphometric parameters of histological preparations of bone tissue was obtained.

To confirm the effectiveness of the proposed method, it was tested in 50 expert cases with a reliably known age. The accuracy of determining age was as follows:
up to 1.5 years - 80% of cases;
from 1.5 to 2 years - 14% of cases;
from 2 to 3 years - 6% of cases (putrefactive changes in bone tissue).

Compared with existing analogues and prototype, the proposed method for determining the age of a person has the following advantages:
1. Allows you to determine the age of a person (in particular, in the range from 18 to 30 years) with an accuracy of 1.5-2 years.

 2. Allows you to use for research only those structures of bone tissue that can be reliably differentiated, which reduces the likelihood of errors.

 3. Allows the use of bone tissue samples from other anatomical regions than in the previous methods (a fragment of the third rib from the zone of transition of bone tissue to the cartilage on the left, as well as the diaphysis and lower epiphysis of the tibia on the left), which is especially important in the absence of a complete set of bones in the case of damage or dismemberment of the corpse.

 4. It allows you to use a computer-based image analysis system for measurements and subsequent calculations, which ensures high accuracy of the results, saving working time and ample opportunities for documenting and monitoring the work of experts.

 It should be noted that the use of original parameters - the ratio of the areas of cartilage and bone tissue and the extent of the active osteogenesis zone in the transitional zone of the longitudinal section of the rib, the diameter of the Haversian canals of the endotrabecular osteons in the tibia epiphysis, the number of endotrabular osteons in the tibia diaphysis, characterizing age-related changes the interval from 18 to 50 years, as well as the use of a complex of other parameters with them and preliminary breakdown by age The methods with the help of qualitative parameters are not described in the literature and are not obvious, and the solution we have proposed is obtained as a result of a large series of our own studies in accordance with the goal. Thus, the present invention meets the criteria of originality, novelty and inventive step.

An example of the practical application of the method
To determine the age of a person by means of a quantitative histological examination of bone tissue samples, fragments of the third rib on the left from the zone of transition of bone tissue to cartilage (approximately five centimeters long), as well as distal pineal gland (including articular cartilage) and diaphysis (at the border of the lower and middle third) of the tibia are taken bones on the left. The material is fixed in a 10% neutral formalin solution, after which blocks about 5 mm thick are cut out from it. In the manufacture of longitudinal sections of the epiphysis of the tibia and ribs, pieces of approximately 1 cm ² are cut, including the transition zone of the bone tissue into the cartilage, and in the manufacture of cross sections of the diaphysis of the tibia and ribs, they contain the entire cross section.

 Next, decalcification of the blocks from the lower pineal gland and the tibia diaphysis, as well as longitudinal and transverse sections of the ribs in a 12% solution of nitric acid and standard alcohol wiring are carried out. Samples of the ribs are poured into paraffin, tibia into celloidin. Using a sled microtome, sections of bone tissue 5-7 microns thick for ribs and 10 microns for tibia are made. Staining is performed with hematoxylin and eosin according to standard methods [4].

 In addition, from the zone at the border of the middle and lower third of the diaphysis, a cross section 450–600 mm thick is cut out, from which an undecalcified bone tissue preparation is further made. To do this, after standard alcohol wiring, the blocks are impregnated with resin or plastic intended for pouring undecalcified bone tissue samples according to the standard scheme. Sections 100 microns thick are made from blocks filled into a solid medium using a cutting microtome, they are freed from the pouring medium using a special solvent, and they are stained with a 0.1% solution of alizarin red C in distilled water, after which they are enclosed in immersion oil on a glass slide and cover with a coverslip.

 The study of histological preparations is carried out using a computer image analysis system, including a light microscope that allows the connection of a video camera, a video camera, a computer designed to work with detailed graphics, a special board that connects the computer to the video camera, a printer, and a graphic editor that allows quantitative description of images.

 First, qualitative signs are determined: in the transition zone of the rib - the presence and severity of the layers of cartilage, in the pineal gland of the tibia - the presence or absence of a growth line, the presence or absence of synostosis, the thickness of the bone trabeculae, the presence and number of endotrabular osteons, the thickness of the subchondral plate, the ratio of myeloid and adipose tissue in the bone marrow cavities of the rib. Based on the listed qualitative characteristics, an individual is assigned to a certain age group (up to 18 years old, 18-30 years old, 18-32 years old, 27-50 years old, over 50 years old).

 Quantitative measurements are carried out using a graphical editor (for example, Adobe PhotoShop [8]) according to the program of primary features developed in accordance with generally accepted rules of morphometric studies [1, 2]. The following signs are measured in the field of view (or individual of these signs as the bone structures are preserved).

On a cross section of the III rib:
1 - the length of the cortical layer;
2 - the area of the cortical layer;
3 - the number of osteocytes;
4 - the area of myeloid tissue;
5 - the area of adipose tissue.

On a longitudinal section of the III rib:
6 - the area of cartilage in the transition zone;
7 - the area of bone tissue in the transition zone;
8 - the length of the osteogenesis zone;
9 - the length of the inner surface of the cartilage.

On a cross section of the tibial epiphysis:
10 - area of the trabecular bone;
11 - the length of the trabecular surface;
12 is the diameter of the Haversian canals of the endotrabecular osteons.

On a cross section of undecalcinized tibia diaphysis:
13 - the minimum diameter of the Haversian channel;
14 - the minimum diameter of the osteon;
15 - the number of osteons;
16 - the number of osteons with a rebuilt central department;
17 - the number of osteons, brightly stained with alizarin.

On a cross section of decalcified tibial diaphysis:
18 is the area of the layer of the outer general lamina;
19 - the area of the layer of the inner master plates;
20 is the length of the cortical layer;
21 - the number of endotrabecular osteons.

 The initial field of view corresponds to the upper left portion of the drug, then the slide is shifted from left to right and from top to bottom. At the same time, when moving the slide, overlapping with the previous fields of view is avoided. The number of studied visual fields for each particular sign for different individuals is different, which is determined by the size of the preparation, morphological features of the structure of the bone tissue of the individual, the degree of preservation of the measured structures, etc.

 So, for example, to calculate the ratio of the areas of cartilage and bone tissue, a transition zone is first found on the preparation of a longitudinal section of the rib. The area of cartilage and bone tissue is measured in trabeculae located near the inner surface of the cartilage, in each selected field of view in series. The results are entered into a database where they calculate the average value of each area and then their ratio.

The resulting resulting sign is introduced into the regression equation calculated for the age group from 18 to 30 years:
AGE = 31.84-0.112Q ₃₄ -84.67Q ₅ -0.078Q ₇ ± 2.048,
where AGE is the biological age in years;
Q ₅ - the ratio of the areas of cartilage and bone tissue in the transition zone of the longitudinal section of the rib;
Q ₃₄ is the average thickness of the layer of the inner general plates of the tibia diaphysis;
Q ₇ - the average thickness of the cortical layer of the ribs.

 Measurements of other parameters are carried out similarly and for each age period its own regression equation is calculated. The measurement results are used to select a model for determining the age corresponding to the given expert case, as well as to calculate the age according to the selected regression equation.

The economic effect of the proposed method
Putting into practice the proposed method for determining a person’s age by morphometric parameters of histological preparations of bone tissue has a direct economic effect, since it saves experts working time and provides objective results, reducing the need for repeated examinations.

Sources of information
1. Avtandilov G.G. Medical Morphometry: A Guide. - M .: Medicine. - 1990 - 384 s.

 2. Avtandilov G. G. Computer microtelemetry in diagnostic histocytopathology. - M .: RMAPO. - 1996 .-- 256 s.

 3. Gladyshev Yu. M. Microscopic structures of bone tissue and their forensic value: Diss. Dr. med. sciences. - Voronezh. - 1965 - 318 s.

 4. Microscopic technology: Guide. // Ed. D.S. Sarkisova and Yu. L. Perov. - M .: Medicine. - 1996 .-- S. 7-50.

 5. Mordasov V.F. Forensic medical examination of a person’s age according to the microstructure of the femur: Microscopic and X-ray diffraction study: Diss. Cand. honey. sciences. - Voronezh. - 1988 - 286 p.

 6. Nainis J. -V. Identification by proximal limb bones. - Vilnius: Mintis. - 1972

 7. Osipenkova-Vichtomova TK Forensic histological examination of bones. - M .: VIKRA. - 2000. - 144 p.

 8. Adobe PhotoShope 4.0. User's manual. Adobe Systems Inc. 381 P.

 9. Lozupone E., Favia A. The structure of spongious trabeculae in relation to age in man.//Boll. Soc. Ital. Biol. Sper. - 1995. - Vol. 71. - 7-8. - PP. 175-180.

 10. Lynnerup N., Thomsen J.L., Frohlich B. Intra- and inter-observer variation in histological criteria used in age at death determination based on femoral cortical bone.// Forensic Science International. - 1998. - Vol. 91. - 3. - PP. 219-230.

 11. Stout S.D., Dietze W.H., Iscan M.Y., Loth S.R. Estimation of age at death using cortical histomorphometry of the sternal end of the fourth rib. // J. Forensic Science. 1994. Vol. 39. - 3. - PP. 778-784.

Claims (1)

 A method for determining a person’s age by morphometric parameters of histological preparations of bone tissue, characterized in that they additionally measure the extent of the active osteogenesis zone, the ratio of the areas of cartilage and bone tissue in the transition zone of the longitudinal section of the III rib, the diameter of the haversian canals of the endotrabular osteons in the section of the tibial pineal gland and the number of endotrabecular osteons in the slice of the tibia diaphysis, the obtained data are introduced into the regression equations, as a result Calculation of which receive the age of the person.