RU194059U1 - Model of the subaxial cervical spine - Google Patents

Abstract

The utility model relates to medicine. The subaxial model of the cervical spine consists of identical anatomically accurate wooden vertebrae. The space between the vertebral bodies is made of silicone polymer. Each vertebra is made on the basis of an anatomically accurate three-dimensional computer model of a subaxial cervical vertebra from solid wood. The utility model provides the opportunity to study the strength and fixing properties of vertebral retainers with various types of damage, as well as the possibility of static and dynamic studies. 5 ill.

Description

The utility model relates to the field of medicine and biotechnology, and in particular to a method for manufacturing and using a model of the cervical spine.

Closest to the proposed device are models of the cervical spine of various manufacturers (3B Scientific, Maximed), made of plastic material.

The disadvantages of the prototype are:

1. the need to use for the production of material models of expensive special equipment;

2. The model is static, since the gaps between the vertebral bodies are made of solid material;

3. It does not make it possible to reliably evaluate the strength characteristics of fixation devices, since the plastic material is not similar to the bone tissue of the cervical vertebra in its properties.

Therefore, the following tasks were posed - the creation of an anatomically accurate model of the subaxial part of the cervical spine to study the strength and fixing properties of vertebral retainers for various types of injuries.

Making a model of the subaxial part of the cervical spine includes creating a three-dimensional model of the subaxial cervical vertebra in the Blender 2.78c program, making the model on a milling machine, and combining the elements into a single model.

In the manufacture of a three-dimensional model of the fifth cervical vertebra, the method of computer polygonal modeling was used, during which the main functions and tools of Blender 2.78c were used (Fig. 1-4).

When choosing a material for the manufacture of the model, the basic principles of bone tissue biomechanics are taken into account:

1) The bone structure is both rigid and elastic, therefore it requires the use of materials with rigid and elastic properties.

2) The optimal model in its properties should be similar to living tissue, that is, have elasticity, have a stress – strain diagram close to it, and the hysteresis inherent in the tissues in the load – unload diagram.

3) In biological systems (body tissues and plants), there is no direct relationship between the stress and strain when a load is applied to living tissues, corresponding to Hooke's law. There is a hysteretic relationship between stress and strain under load and unload conditions, which is expressed in the elastic behavior and the return of the strain (more than 2%) to its original state. The return deformation in biological materials is an order of magnitude higher than the return deformation in "non-living" metal or other solid materials [5].

The material for the manufacture of the model was chosen wood, as its biomechanical characteristics are most comparable with bone tissue [3]. For the production of vertebral models, solid wood species were used, the density characteristics of which are to a certain extent close to those of bone tissue, and their differences do not significantly affect the results of the study [1]. According to the reference literature, the specific compressive strength of oak wood across the fiber is E = 84.1 × 106 Nm-2, while the specific compressive strength of the body of the third cervical vertebra is E = 70.0 × 105 Nm-2 [2, 4].

The sample was machined from hardwood (beech) on a three-coordinate numerically controlled machine.

The space between the vertebral bodies is made of silicone, which served as an analogue of the intervertebral disc and gives the spinal segment elastic properties (Fig. 5). As a result, the model has become dynamic. The model provides mobility in each motor segment within the limits close to natural, and allows carrying out static and dynamic studies.

As a result, the created anatomically accurate model of the subaxial part of the cervical spine is a useful, inexpensive tool in serial studies related to the study of strength and fixation properties of original and standard vertebral fixators, where a large amount of consumable material of the same type is needed. The utility model can be used when conducting serial tests under the influence of external loads, as well as when learning the technique of various options for fixing the cervical spine.

In addition, the model of the subaxial part of the cervical spine, made on the basis of three-dimensional modeling, makes it possible to substantiate and introduce into clinical practice innovative methods for fixing vertebral segments with various types of damage.

List of references:

1. Barysh A.E., Mikhailov S.R. Physical model for experimental biomechanical research of the cervical spine // Orthopedics. - 2006. - No. 1 - S. 55-61.

2. Berezovsky V. A., Kolotilov N. N. Biophysical characteristics of human tissues: a Handbook. - K .: Science. Dumka, 1990 .-- 224 p.

3. Ugolev B.N., Borovikov A.M. Wood Handbook: Handbook / Ed. B.N. Ugoleva. - M .: Forest. industry, 1989. With 12.

4. Feodosiev V.I. Strength of materials. - M .: Nauka, 1972.- 544 p.

5. Khlusov I.A. Fundamentals of biomechanics of biocompatible materials and biological tissues: a training manual / Khlusov I.A., Pichugin V.F., Ryabtseva M.A. - Tomsk: Publishing House of the Tomsk Polytechnic University, 2007. With 47-49.

Claims (1)

The model of the subaxial part of the cervical spine consists of identical anatomically accurate wooden vertebrae, the space between the bodies of which is made of silicone polymer, and each vertebra is made on the basis of an anatomically accurate three-dimensional computer model of the subaxial cervical vertebra of solid wood.

Images