RU2817974C1 - Method of enclosing bone preparations in epoxy resin for preserving reconstructed bone fragments for subsequent scanning on computer tomograph - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to a method for embedding a bone preparation in epoxy resin for preserving reconstructed bone fragments for the purpose of subsequent scanning on a computer tomograph. In accordance with the proposed method, bone fragments are soaked in technical acetone for 3 days, followed by drying at room temperature for 50 minutes, followed by soaking in absolute isopropanol for 6 hours, followed by drying at room temperature for 30 minutes, then gluing matched bone fragments by means of adhesive composition based on cyanoacrylate, then, after curing of the adhesive composition, the bone preparation is placed in a silicone mould and embedded in an epoxy resin for thick-layer filling.

EFFECT: invention provides reconstruction, fixation and preservation of bone material with traumatic injuries.

1 cl, 5 dwg, 1 ex

Description

The invention relates to medicine, namely to morphology, forensic medicine, pathological anatomy, osteology, radiation studies, traumatology, as well as museums and anthropology. Can be used as a visual teaching aid in the departments of pathological anatomy, surgery, traumatology, forensic medicine and radiology.

The study of human bone and joint apparatus is of particular importance for morphological sciences in general and forensic practice in particular. One of the features of this material is the multicomponent nature of its components. At the same time, it should be noted that the bone and joint material represented by preparations of normal anatomy is very different from the pathological material.

There is a high incidence of injury in the WHO European Region. In 2015, unintentional and intentional injuries were responsible for 530,000 deaths. Fatal outcome as a result of traumatic injury ranks third in the structure of overall mortality according to WHO world statistics. It is also significant that a relatively high proportion in the structure of all injuries is occupied by comminuted and multi-comminuted fractures, which especially complicates the task when working with bone material. Due to the large number of fragments identified during the evaluation of a comminuted fracture, there is a high risk of losing some bone fragments, which may complicate bone reconstruction to assess the nature of the damage when reviewing the circumstances of the case.

The issue of preserving bone fragments becomes especially relevant in the case of exhumation of remains. In many cases, extremely precise preservation of exhumation material is required, since exhumation is often carried out as part of resonant or historically significant processes.

Separately, it is worth noting the importance of preserving bone material intact for the needs of anthropological research, in which the assessment of the species, age, sex, and some features of an individual’s life requires the presence of a visually intact or reconstructed object with extreme accuracy.

Fragments of solid remains (bones) of famous historical figures are of high historical significance, the careful and most visible preservation of which has a certain cultural significance for visitors to thematic museums, exhibitions, as well as for historians.

In many ways, the problem of comparing and long-term preservation of bone fragments in a reconstructed form, provided that their external qualities are preserved and the possibility of visually assessing the number of fragments and the nature of the fracture, both with the naked eye and using multislice computed tomography (MSCT), is solved through the use of the preliminary reconstruction method in combination with fixation of fragments with an adhesive composition and the final encapsulation of the resulting preparation in a special epoxy resin for thick-layer filling.

There are a number of known methods for reconstructing bone fragments for further study of traumatic injuries and demonstration of injuries at the departments of traumatology, surgery and forensic medicine.

For example, in the framework of modern forensic medical examination, a routine method is used to temporarily fix bone fragments using a plastic material with adhesive properties (plasticine).

The disadvantages of this method are the instability of fixed bone fragments, the fragility of the reconstruction and the difficulty of transporting the bone material being studied in its entirety.

There is a known method of fastening bones for further study using soft wire. After mechanical and thermal cleaning of bone fragments, comparisons are made of damaged parts of the bone that are congruent to each other. The bones are fastened with soft thin wire or a thin wire through holes drilled in the edges, the diameter of which should not be much greater than the thickness of the wire, and the holes themselves should not be located too close or far from the edges of the fracture. The mobility of fragments must be prevented by tightening and twisting the wire.

The disadvantages of this method are the need for additional damage to the bone as a result of drilling holes in the edges of the fragments, which can eventually lead to crumbling or destruction of the edges of the compared surfaces. It is also worth noting that the use of a metal wire creates artifacts in CT examinations.

There is a known method described by G. von Hagens, which we take as a prototype (von Hagens G, Tiedemann K, Kriz W. The current potential of plastination. Anat Embryol (Berl). 1987;175(4):411-21. doi: 10.1007/BF00309677. PMID: 3555158). It involves impregnating biological samples with reactive polymers in a vacuum. The main stages of this method are: preparation of thin sections of the desired sample, cold dehydration in technical acetone by freezing, degreasing, forced impregnation of epoxy resin under vacuum and final curing of the preparation in an oven.

The disadvantages of this method are the impregnation of all structures and tissues of the drug with epoxy resin, which leads to the replacement of the contents of cells and tissues and disruption of their structures; such impregnation completely disrupts the differentiation of tissues when examined on a computed tomograph.

The technical result consists in developing a method for reconstructing, fixing and preserving bone material with traumatic injuries, by comparing congruent bone fragments with subsequent encapsulation in a special epoxy resin for further scanning using a computed tomograph.

The technical result is achieved by soaking bone fragments in a solution of technical acetone for 3 days, followed by drying at room temperature for 50 minutes, after which they are soaked in absolute isopropanol for 6 hours, followed by drying at room temperature for 30 minutes, then the compared bone fragments are glued together using an adhesive composition based on cyanoacrylate. Then, after the adhesive composition has cured, the preparation is placed in a silicone mold and encased in a special epoxy resin for thick-layer casting. After the epoxy resin mass has cured, the prepared bone preparation is removed from the mold, after which the preparation is ready for exposure.

THE INVENTION IS EXPLAINED BY FIGURES (Fig. 1-5)

In fig. 1 – Sample of bone material routinely reconstructed using a material with adhesive properties (plasticine);

In fig. 2 – Bone fragments of a long tubular bone before they are fixed with an adhesive composition;

Figure 3 – Reconstructed long tubular bone. Fracture lines are visually determined;

Figure 4 – Reconstructed long tubular bone encased in epoxy resin;

In fig. 5 – CT scan with 3D reconstruction of long bone, mechanically reconstructed and embedded in epoxy resin.

The method is carried out as follows: bone fragments obtained as a result of exhumation of the remains of the body are compared according to their topographic characteristics and the congruence of the compared surfaces, which makes it possible to assess the completeness of the fragments of a particular bone. If the fragments have already been assessed previously and were previously fixed with plasticine, mechanical cleaning of the bone from plasticine is performed using medical instruments. Then the bone fragments are kept in a solution of technical acetone for 3 days, followed by drying at room temperature for 50 minutes, after which they are soaked in absolute isopropanol for 6 hours, followed by drying at room temperature for 30 minutes, then the bone fragments are glued together using a cyanoacrylate-based adhesive manually, according to their topographic characteristics and the congruence of the compared surfaces. Then, after the adhesive composition has cured, the preparation is placed in a silicone mold and encased in a special epoxy resin for thick-layer casting. After the epoxy resin mass has cured, the prepared bone preparation is removed from the mold, after which the preparation is ready for exposure.

Next, the drug can be scanned using a multislice computed tomograph (MSCT). Scanning is carried out in a classical mode, similar to data collection in a conventional computed tomograph in a spiral mode: voltage on the tube is 120 kV, X-ray exposure is 200 mA s, pitch is 0.5, a large focus of the X-ray tube is used, moving at a speed of 1 revolution per 0.5 s.

EXAMPLE OF PRACTICAL USE OF THE METHOD

The study was conducted at the Institute of Human Morphology named after. A.P. Avtsina.

Bone traumatological material was selected in the amount of 11 tubular, 5 flat, 4 cancellous bones. Fragments of long tubular bones of the upper and lower extremities; flat bones were represented by 2 ribs (V and VI), 3 fragments of the bones of the cranial vault; The spongy bones were represented by 3 calcaneal bones and a fragment of the tibial condyle. The material was subjected to revision of bone fragments, the composition of the samples and the possibility of their comparison were assessed. Next, the bone material was subjected to mechanical cleaning using a surgical scalpel, a Volkmann spoon, a surgical probe, and a dental probe. After that, the fragments, ensuring that each individual sample of bone material was complete, was soaked in technical acetone for 3 days. After the time had elapsed, drying was carried out at room temperature and normal atmospheric pressure for 50 minutes. Next, also ensuring that the samples were complete, they were soaked in absolute isopropanol for 6 hours. After the time had elapsed, drying was carried out at room temperature and normal atmospheric pressure for 30 minutes. The next stage was the repeated comparison of congruent bone fragments, taking into account the completeness of the sample, with their simultaneous fixation using an adhesive composition based on cyanoacrylates. Next, after the adhesive composition had cured, the reconstructed bone preparation was placed in a silicone mold of the appropriate size, after which a mass of pre-prepared special epoxy resin for thick-layer casting was poured into it according to the manufacturer’s instructions.

Once the epoxy resin had cured, the bone specimen of the reconstructed bone embedded in the epoxy resin was ready for CT examination. The specimen was placed on the tomograph table, scanning was carried out in the classical mode, similar to data collection in a conventional computed tomograph in a spiral mode.

As a result of applying the method, 20 bone preparations of reconstructed bones (11 long tubular, 5 flat, 4 spongy) were obtained, preliminarily simultaneously compared and fixed using an adhesive composition based on cyanoacrylate, followed by encapsulation in a special epoxy resin for thick-layer casting. Thus, using bone preparations, visualization of fracture lines was achieved against the background of an artificially restored original bone structure. The almost complete transparency of the epoxy resin allows for a direct visual assessment of the nature and characteristics of the injury. The combination of external visualization with the subsequent use of CT examination opens up opportunities for the highest accuracy of visualization of the lines and nature of the fracture, the number of fragments and the characteristics of the general condition of the bone tissue. The resulting digital images are convenient for storing and transferring to other media and exchanging information between specialists.

The use of a combination of methods opens up new opportunities for areas of activity in anthropology, museum studies, pathological anatomy and forensic medicine. The method used has such advantages as safety of use of the bone preparation, durability of use, lack of toxicity and reduction in the cost of maintaining the preparation due to the absence of the need to replace components of the preservative medium. The use of a computed tomograph allows one to study the characteristics of the traumatological characteristics of a particular reconstructed bone tissue sample. Storing digital CT images allows you to store and share practical and scientifically valuable information with colleagues.

The finished preparation can either be exhibited in thematic museums or departments of morphological and forensic medicine as visual teaching aids, or provided for further evaluation by a forensic expert, including using MSCT.

Claims (1)

A method of enclosing a bone preparation in epoxy resin for preserving reconstructed bone fragments for subsequent scanning on a computed tomograph, characterized in that bone fragments are soaked in technical acetone for 3 days, followed by drying at room temperature for 50 minutes, after which they are soaked in absolute isopropanol for 6 hours, followed by drying at room temperature for 30 minutes, then the compared bone fragments are glued together using an adhesive composition based on cyanoacrylate, then after the adhesive composition has cured, the bone preparation is placed in a silicone mold and encased in epoxy resin for thick-layer casting.