RU208912U1 - A device for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments - Google Patents

Abstract

The utility model relates to medicine, namely to traumatology, orthopedics and neurosurgery, and can be used to model isolated anterior stabilization of the vertebral segment at the C6-C7 level after a three-column injury to measure and evaluate the primary fixation stability of the lower cervical vertebral segments. The device for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after three column injuries for measuring and assessing the primary stability of fixation of the lower cervical vertebral segments is prefabricated, containing a 3D model of the vertebral segment, equipment from two platforms - cranial and caudal, on the edge of the cranial platform has a spherical groove, a ball for contact with the upper traverse of the test machine stand. The 3D model of the vertebral segment consists of two full-sized cervical vertebrae C6 and C7, made as one-piece cast with trapezoidal platforms. There are holes in the corners of the platforms. On the back surface of the platform of the full-sized C6 cervical vertebra, there are stiffening ribs that run along the entire surface of the platform. On the back surface of the platform of the full-sized C7 cervical vertebra, stiffeners are made that run along the entire surface of the platform. A through hole is located on the cranial platform and the caudal platform along the central axis. On the lower surface of the cranial platform, a trapezoid-shaped recess is made corresponding to the platform of the full-sized C6 cervical vertebra. On the lower surface of the caudal platform, a trapezoid-shaped recess is made corresponding to the platform of the full-sized C7 cervical vertebra. At the corners of said recesses, through holes are made with the possibility of connection with the through holes of the platforms of the said C6 and C7 vertebrae for the insertion of fixing devices through them. Three spherical grooves are made on the upper surface of the cranial platform, passing from one to another. The centers of the spherical grooves correspond to the sagittal vertical axis of the cervical spine C2-C7SVA. All mentioned spherical grooves are located on one central axis. The diameters of said spherical grooves are equal to the diameter of said ball. The support for contact with the lower traverse of the test machine stand is made of a base in the form of a straight triangular prism and a protrusion made in the form of a triangular prism, the side face of which is a continuation of the leg of the base. There is a through hole on the base, the latter is intended for alignment with the hole of the caudal platform and the subsequent introduction of a fixing device, and the edge of the caudal platform is made with the ability to fit snugly against the ledge of the support. The advantages of the proposed device for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after three column injuries for measuring and evaluating the primary stability of fixation of the lower cervical vertebral segments in comparison with existing ones are that the validity of the data obtained in the experiments is high, since the device is made made of durable material - polyamide (grade PA2200 / PA-12), which has physical and strength properties close to human bone, contains a 3D model of the spinal segment, which has similar physical and mechanical properties to human cervical vertebrae, on platforms of a trapezoidal shape of the 3D model the vertebral segment is made with stiffeners to ensure no deformation when a load is applied. The device anatomically and physiologically reproduces the structure of the human cervical spine, which allows you to conduct experiments with parameters corresponding to human anatomy, which increases the validity of the results obtained in the experiments. The device can be used in flexion tests, strength tests of implants, tests of fixed vertebral segments for fatigue failure in cyclic tests, stability tests of vertebral segments after their fixation with implants in VITRO when measuring and evaluating the primary stability of fixation of the lower cervical vertebral segments in three columnar injuries due to support corresponding to the slope of the first thoracic vertebra (Tlslop). The device does not depend on the variability of the physiological properties of the bone (for example, the properties of the bone in animals, cadavers, etc.), which increases the validity of the measured parameters in the experiment. This leads to the fact that the device claimed by us allows us to correctly calculate the indicators of primary stability of fixation of the lower cervical vertebral segments with three columnar injuries, determine the optimal treatment tactics, and choose the volume of surgical treatment. The device for modeling isolated anterior stabilization of the vertebral segment at the C6-C7 level after a three-column injury for measuring and assessing the primary stability of fixation of the lower cervical vertebral segments is made of high-quality, high-quality, modern materials using modern equipment, using modern technologies.

Description

The utility model relates to medicine, namely to traumatology, orthopedics and neurosurgery, and can be used to model isolated anterior stabilization of the vertebral segment at the C6-C7 level after a three-column injury to measure and evaluate the primary fixation stability of the lower cervical vertebral segments.

Devices are known for modeling isolated anterior stabilization of the spinal segment at the C6-C7 level after a three-column injury to measure and evaluate the primary fixation stability of the lower cervical vertebrates (Panjabi, M.M. (1998). Cervical Spine Models for Biomechanical Research. Spine, 23(24 ), 2684-2699. doi: 10.1097/00007632-199812150-00007), which are biomechanical models consisting of several groups.

The first group - devices for modeling isolated anterior stabilization of the spinal segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebrates, which are blocks interconnected, made of ultra-high molecular weight polyethylene (physical models).

The disadvantages of these devices are that there is a high risk of incorrect measurement and evaluation of the primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries, since there is no anatomical and physiological identity with the human spine and the ability to set the parameters of the sagittal balance.

The second group - devices for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments, consisting of vertebral segments of animals.

The disadvantages of these devices are that there is a high risk of incorrect measurement and evaluation of the primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries, since there is no anatomical identity and physiological accuracy with the human spine, the strength properties of animal bones are lower than those of human bones. The risk of incorrect indicators is also high due to the fact that it is not always possible to provide an equivalent biomechanical load on the implant, due to a discrepancy between the anatomy and strength of the animal bone tissue. Difficult to use as not all animals are suitable. The animal must have the kinematics, kinetics, size of the vertebrae and the rate of reparative osteogenesis as close as possible to the human.

The third group - devices for modeling isolated anterior stabilization of the spinal segment at the C6-C7 level after a three-column injury to measure and evaluate the primary fixation stability of the lower cervical vertebral segments, which are mathematical computer models developed on the basis of mathematical equations that include the geometry and physical characteristics of the spine person.

The disadvantages of these devices lie in the fact that the simulation results are predetermined by the properties of the selected simulation method. Since these models are purely mathematical, the validity of the results obtained must be verified experimentally. Forecasts are valid only within the assumptions and limitations that are used in the calculations.

Devices are known for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments (Friis, E.A., Arnold, PM, & Goel, VK (2017). Mechanical testing of cervical, thoracolumbar, and lumbar spine implants Mechanical Testing of Orthopedic Implants, 161-180 doi: 10.1016/b978-0-08-100286-5.00009-3), consisting of human vertebral segments.

The disadvantages of these devices are that the use of these devices is not humane, not ethical. There is a high risk of incorrect measurement and assessment of the primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries, due to the fact that the bone is anisotropic, has elastic and viscous properties, and when it passes into the cadaver bone, it loses these properties. It is almost impossible to select human cadavers with identical mechanical and morphological properties for research.

A device is known for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments (Lastevsky A.D., Roerich V.V., Bataev V.A., Veselov S. B. Fixing properties of ceramic implants during ventral stabilization of subaxial cervical segments in the experiment (literature review and results of own research) // Modern problems of science and education. - 2018. - №6 .; URL: http://science-education.ru/ ru/article/view?id=28429) taken as a prototype, containing a 3D model of the spinal segment consisting of a full-size C5 cervical vertebra made as a one-piece cast with a trapezoid platform and a full-size C6 cervical vertebra made as a one-piece cast with a trapezoid-shaped platform, holes are located at the corners of the platforms, equipment consisting of two platforms, cranial platform and caudal platform, made in the form parallelepiped, on the edge of the cranial platform there is a spherical groove, and a ball made of durable materials. A 3D model of the spinal segment is attached to the rig with screws through the holes at the corners of the trapezoidal platforms. A ball is placed in a spherical groove on the cranial platform.

The disadvantages of this device are that it is limited in use and can only be used for flexion tests when measuring and assessing the primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries, as it has a spherical groove located on the edge of the cranial platform, designed to simulate flexion head and determination of the stability of the vertebral segment, fixed by the implant to the flexion load.

The technical result of the proposed utility model is the creation of a device free from the above disadvantages.

The specified technical result is achieved by the fact that the device for modeling isolated anterior stabilization of the spinal segment at the level of C6-C7 after a three-column injury for measuring and assessing the primary stability of fixation of the lower cervical vertebral segments is prefabricated, containing a 3D model of the spinal segment, equipment from two platforms - cranial and caudal, on the edge of the cranial platform there is a spherical groove, a ball for contact with the upper traverse of the test machine stand, a 3D model of the spinal segment, consisting of two full-sized cervical vertebrae C6 and C7, made as one-piece cast with trapezoidal platforms, there are holes at the corners of the platforms, on the back surface of the platform of the full-size cervical vertebra C6, stiffening ribs are made, passing over the entire surface of the platform; th platform and the caudal platform along the central axis there is a through hole, on the lower surface of the cranial platform there is a trapezoid-shaped recess corresponding to the platform of the full-sized C6 cervical vertebra, on the lower surface of the caudal platform a trapezoid-shaped recess is made corresponding to the platform of the full-sized C7 cervical vertebra, at the corners of the mentioned recesses through holes are made with the possibility of connection with the through holes of the platforms of the mentioned C6 and C7 vertebrae for insertion of fixing devices through them, three spherical grooves are made on the upper surface of the cranial platform, passing from one to another, the centers of the spherical grooves correspond to the sagittal vertical axis of the cervical spine C2- C7SVA, all mentioned spherical slots are located on the same central axis, the diameters of said spherical slots are equal to the diameter of the mentioned ball, support for contact with the lower crosshead of the testing machine stand The base is made of a base in the form of a straight triangular prism and a protrusion made in the form of a triangular prism, the lateral face of which is a continuation of the leg of the base, on the base there is a through hole, the latter is designed to be aligned with the hole of the caudal platform and the subsequent introduction of a fixing device, and the edge of the caudal platform made with the ability to fit snugly against the protrusion of the support.

The claimed utility model is illustrated by the following images, where in Fig. 1 - photograph, general view, 3D model of the spinal segment, fig. 2 - photograph, top view, 3D model of the spinal segment, fig. 3 - photograph, bottom view, 3D model of the spinal segment, fig. 4 - photograph, top view, equipment, cranial platform, fig. 5 - photograph, top view, equipment, caudal platform, fig. 6 - photograph, bottom view, equipment, cranial platform, fig. 7 - photograph, bottom view, equipment, caudal platform, fig. 8 - photograph, top view, support, fig. 9 - photograph, general view, support, fig. 10 - photograph, general view, ball, fig. 11 is a photograph showing the assembly of the cranial platform and a full-size C6 cervical vertebra of a 3D model of the spinal segment, FIG. 12 - photograph shows the assembly of the caudal platform and a full-sized cervical vertebra C7 3D model of the vertebral segment, fig. 13 - photograph, general view, shows the assembly of the cranial and caudal platforms with a 3D model of the spinal segment, fig. 14 - photograph, side view, shows the assembly of the cranial, caudal platforms with a 3D model of the vertebral segment with a support with an implant installed, fig. 15 - photograph, rear view, shows the assembly of the cranial, caudal platforms with a 3D model of the vertebral segment with a support with an implant installed, fig. 16 - photograph, general view, device, fig. 17 - photograph, general view, shows the device in the experiment.

The device for modeling isolated anterior stabilization of the spinal segment at the C6-C7 level after a three-column injury for measuring and assessing the primary stability of fixation of the lower cervical spinal segments is prefabricated and contains a 3D model of the spinal segment (1) made of durable materials, such as polyamide (grade PA 2200/PA-12), consisting of a full-size cervical vertebra C6 (2), made of a solid cast with a platform (3) of a trapezoidal shape, on the back surface of the platform (3) stiffening ribs (4) are made, passing over the entire surface of the platform (3), ensuring the absence of deformation when a load is applied and a full-sized cervical vertebra C7 (5), made as a solid cast with a platform (6) of a trapezoidal shape, on the back surface of the platform (6) there are stiffening ribs (7) passing over the entire surface of the platform (6), ensuring the absence of deformation upon application of a load. There are holes (8) at the corners of the platforms (3, 6). A rig (9) consisting of a cranial platform (10) and a caudal platform (11). The cranial platform (10) and the caudal platform (11) are made of durable materials, such as aluminum alloy (grade D16T), made in the form of a parallelepiped, on the central axis of which there is a through hole (12) for fixation. On the lower surface of the cranial platform (10) there is a recess (13) of a trapezoidal shape corresponding to the platform (3) of the full-sized C6 cervical vertebra (2). On the lower surface of the caudal platform (11), a recess (14) of a trapezoid shape is made, corresponding to the platform (6) of the full-sized C7 cervical vertebra (5). At the corners of the recesses (13, 14) there are through holes (15) for fixing. The recesses (13, 14) are located in such a way that one of the bases of the trapezoid passes through the center of the cranial platform (10) and the caudal platform (11), this allows you to apply various types of loads on the device, for example (axial, flexion). On the upper surface of the cranial platform (10) there are four spherical grooves (16) located on the same central axis, one spherical groove is located on the edge of the cranial platform (10), three other spherical grooves (16) pass from one to another. The centers of the spherical grooves (16) correspond to the sagittal vertical axis of the cervical spine C2-C7SVA, along which the load is carried out in the experiment. They were formed at the point of intersection of the cranial platform with a perpendicular drawn upward from a point on a horizontal plane located 20 mm anteriorly from the craniodorsal angle of the full-sized C7 cervical vertebra (5), while the caudal platform (11) was inclined to the horizon at an angle of 20° and 35°, which corresponds to the slope of the first thoracic vertebra (Tlslop). The spherical grooves are formed in such a way that both with a slope of Tlslop=20° and Tlslop=35°, the parameter C2-C7 SVA will correspond to 20 mm. The diameter of the spherical grooves (16) is 15 mm, derived experimentally. Support (17) made of durable materials, such as aluminum alloy (grade D16T), consisting of a base (18) made in the form of a straight triangular prism and a protrusion (19) made in the form of a triangular prism, the side face of which is a continuation of the leg of the base (eighteen). On the base there is a through hole (20) for fixing. Support (17) in the experiment corresponds to the slope of the first thoracic vertebra (Tlslop). The slope of the first thoracic vertebra (Tlslop) may vary depending on the experimental conditions. The ball (21) is made of durable materials, such as steel (grade ШХ 15), the diameter is 15 mm and corresponds to the diameter of the spherical grooves (16). In the experiment, the ball (21) is in contact with the upper traverse of the bench of the Instron 3369 testing machine through a movable platform consisting of a polished steel plate and roller bearings. It was found in the experiment that the diameter of the spherical grooves (16), equal to 15 mm, ensures that the movable platform of the Instron 3369 testing machine stand and the cranial platform (10) do not contact when the load is transferred to the cranial platform (10) through the ball (21). With an increase in the diameter of the spherical grooves (16), the size of the ball (21) also increases, which corresponds to the diameter of the spherical grooves (16), which leads to an increase in measurement inaccuracy. When the diameter of the spherical grooves (16) and the ball (21) is reduced, the moving platform of the Instron 3369 testing machine touches the cranial platform (10), which also leads to measurement inaccuracies.

The device is used as follows.

Stage 1 - Assembling the device.

The platform (3) of the full size C6 cervical vertebra (2) is inserted into the recess (13) of the cranial platform (10). The holes (8) at the corners of the platform (3) are connected with the holes (15) at the corners of the recess (13) of the cranial platform (10). Fixing devices, such as screws, are inserted through holes (8, 15). The platform (6) of the full size C7 cervical vertebra (5) is inserted into the recess (14) of the caudal platform (11). The holes (8) at the corners of the platform (6) are connected with the holes (15) at the corners of the recess (14) of the caudal platform (11). Fixing devices, such as screws, are inserted through holes (8, 15). Next, a segmental lordotic angle of 6° is formed symmetrically in the frontal and axial projections between adjacent endplates of the full-sized cervical vertebrae C6 (2) and C7 (5) in a standard way. Then, depending on the experimental conditions, an implant consisting of a plate and screws is fixed to full-sized cervical vertebrae C6 (2) and C7 (5) in a standard way. Next, the caudal platform (11) is installed on the base (18) of the support (17), so that the edge of the caudal platform (11) fits snugly against the protrusion (19), aligning holes (12) and (20). Through the holes (12, 20) enter the fixing devices, such as screws.

Stage 2 - Device operation.

The assembled device for modeling isolated anterior stabilization of the vertebral segment at the C6-C7 level after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments is installed on the stand of the Instron 3369 testing machine. Depending on the experimental conditions, the ball (21) is placed in spherical grooves ( 16) cranial platform (10). Then the polished steel plate of the moving platform of the test bench of the Instron 3369 test machine is installed on the ball (21). The top crosshead of the Instron 3369 test machine is then lowered down until it contacts the roller bearings on the movable platform. Next, the experiment is performed.

An example of a specific use of the claimed device.

In this experiment, two series of tests are carried out. An axial load along the sagittal vertical axis C2 - C7 SVA is applied to the device for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments. In the first series of tests, the parameter value TlSlope=20° is used, in the second series of tests TlSlope=35°. In both series of tests, the biomechanical parameters of the sagittal cervical balance of a healthy person are set corresponding to the following values:

TlSlope (tilt angle of Th1 vertebra)=25.7±6.4,

C2 - C7 SVA (sagittal vertical axis of the cervical spine) = 20 mm,

NT (neck inclination) angle between the perpendicular to the horizontal plane and the line connecting the middle of the endplate Th1 and the top of the manubrium of the sternum=43.7±6.1,

TIA (thoracic entry angle) the angle between the line perpendicular to the Th1 Slope endplate and the straight line connecting the center of the Th1 vertebral endplate and the apex of the manubrium of the sternum=69.5±8.6.

A device for modeling isolated anterior stabilization of the vertebral segment at the level of C6-C7 after a three-column injury to measure and evaluate the primary stability of fixation of the lower cervical vertebral segments is installed on the stand of the Instron 3369 testing machine. The ball (21) is placed in the spherical groove (16) of the cranial platform (10 ). Next, the polished steel plate of the moving platform of the Instron 3369 testing machine stand is mounted on the ball (21). The top crosshead of the Instron 3369 test machine is then lowered down until it contacts the roller bearings on the movable platform. In this experiment, an injection needle pointer attached to the cranial platform (10) and a ruler attached to the caudal platform (11) were used. The stand of the Instron 3369 testing machine carries out a static movement of the traverse at a speed of 1 mm/min until a displacement of the full-size C6 (2) cervical vertebra relative to the full-size C7 (5) cervical vertebra is not less than 5 mm. Offset fixing is determined by moving the pointer relative to the graduated ruler. The Instron 3369 test machine bench records load values from two test runs and generates load-strain curves. Fixes the values of the following parameters in two series: neutral zone (NZ), elastic zone (EZ).

Results: the value of the neutral zone (NZ) parameter tends to zero in both series, which indicates the absence of range of motion in the system. Device for measuring and assessing the primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries - implant. With an increase in the slope of the first thoracic vertebra (Tlslop) from 20° to 35°, the value of the elastic zone (EZ) increases from the first series of 1.25 ± 0.29 mm to 2.8 ± 0.21 mm of the second series, which indicates about the influence of the parameter (Tlslop) on the magnitude of the elastic deformation of the system. a device for measuring and evaluating the primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries - an implant. Subsequently, the data is subjected to statistical processing using the criteria of descriptive statistics.

In this experiment, a device for modeling isolated anterior stabilization of the spinal segment at the C6-C7 level after a three-column injury to measure and evaluate the primary fixation stability of the lower cervical vertebral segments measures and evaluates in vitro in biomechanical flexion and axial load tests the primary fixation stability of the lower cervical vertebral segments in their three-column lesions using the values of the parameters of the cervical sagittal balance.

The advantages of the proposed device for modeling isolated anterior stabilization of the vertebral segment at the C6-C7 level after a three-column injury for measuring and evaluating the primary stability of fixation of the lower cervical vertebral segments in comparison with the existing ones are that the validity of the data obtained in the experiments is high, since the device is made made of durable material - polyamide (grade PA2200 / PA-12), which has physical and strength properties close to human bone, contains a 3D model of the spinal segment, which has similar physical and mechanical properties to human cervical vertebrae, on platforms of a trapezoidal shape of the 3D model the vertebral segment is made with stiffeners to ensure no deformation when a load is applied. The device anatomically and physiologically reproduces the structure of the human cervical spine, which allows you to conduct experiments with parameters corresponding to human anatomy, which increases the validity of the results obtained in the experiments. The device can be used in flexion tests, strength tests of implants, tests of fixed vertebral segments for fatigue failure in cyclic tests, stability tests of vertebral segments after their fixation with implants in VITRO when measuring and evaluating the primary stability of fixation of the lower cervical vertebral segments in three-column injuries, due to support corresponding to the slope of the first thoracic vertebra (Tlslop). The device does not depend on the variability of the physiological properties of the bone (for example, the properties of the bone in animals, cadavers, etc.), which increases the validity of the measured parameters in the experiment. This leads to the fact that the device claimed by us allows you to correctly calculate the indicators of primary stability of fixation of the lower cervical vertebral segments in case of three-column injuries, determine the optimal treatment tactics, and choose the amount of surgical treatment.

The device for modeling isolated anterior stabilization of the vertebral segment at the C6-C7 level after a three-column injury for measuring and assessing the primary stability of fixation of the lower cervical vertebral segments is made of high-quality, high-quality, modern materials using modern equipment, using modern technologies.

Claims (1)

The device for modeling isolated anterior stabilization of the spinal segment at the level of C6-C7 after a three-column injury for measuring and assessing the primary stability of fixation of the lower cervical vertebral segments is prefabricated, containing a 3D model of the spinal segment, equipment from two platforms - cranial and caudal, on the edge of the cranial platform there is a spherical groove, a ball for contact with the upper traverse of the test machine stand, characterized in that the 3D model of the spinal segment, consisting of two full-sized cervical vertebrae C6 and C7, made as a solid cast with trapezoidal platforms, there are holes at the corners of the platforms, on the back surface of the platform of the full-size cervical vertebra C6, stiffening ribs are made, passing over the entire surface of the platform; in the form along the central axis there is a through hole, on the lower surface of the cranial platform there is a trapezoid-shaped recess corresponding to the platform of the full-sized cervical vertebra C6, on the lower surface of the caudal platform there is a trapezoid-shaped recess corresponding to the platform of the full-size cervical vertebra C7, at the corners of the mentioned recesses there are through holes with the possibility of connection with the through holes of the platforms of the mentioned C6 and C7 vertebrae for the introduction of fixing devices through them, three spherical grooves are made on the upper surface of the cranial platform, passing from one to another, the centers of the spherical grooves correspond to the sagittal vertical axis of the cervical spine C2-C7SVA, all of the above spherical grooves are located on the same central axis, the diameters of the said spherical grooves are equal to the diameter of the said ball, the support for contact with the lower traverse of the testing machine stand is made of a base in the form de a straight triangular prism and a protrusion made in the form of a triangular prism, the side face of which is a continuation of the leg of the base, there is a through hole on the base, the latter is designed to be aligned with the hole of the caudal platform and the subsequent introduction of a fixing device, and the edge of the caudal platform is made to fit snugly to the protrusion of the support.

Images