RU104061U1 - DYNAMIC SIMULATOR-CORRECTOR OF ANATOMIC AND BIOMECHANICAL CHARACTERISTICS OF THE SPINE AND SHOULDER BELT - Google Patents

Abstract

 1. A dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle, containing straps and fasteners, characterized in that it is made according to the modular principle in the form of structurally integrated elements in one device and contains a hygienic underwear knitted substrate, to which a supporting pelvic girdle is attached below containing a base in the form of a multilayer cloth panel with a width of at least 120 mm shorter along the upper edge compared to the lower edge with attached to at the ends of at least 2 pairs of belts equipped with fabric fasteners that are adjustable along the grip length, while open and expanded upward pockets are sewn to the supporting pelvic girdle at the places of the supposed location of the cassette clips of the vertical flat springy modules, fabric containers with flat ones placed in them zig-shaped springs located transversely in the thickness of the supporting pelvic girdle in individually varying locations, located in the pocket in the center of the supporting pelvis of the belt, a support platform made in the form of a plastic plate with three cassette clips of vertical flat spring modules rigidly fixed on it from the outside, mechanically adjustable in depth by a set of interchangeable interchangeable corrective inserts of various lengths placed inside, one of three cassette clips being placed in the center of the plate and two - along the edge, and on the inner side of the plate along the upper edge there is a shock absorber made of polyethylene foam with an individually shaped

Description

The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle belongs to medical equipment and can be used in neurology, orthopedics and rehabilitation.

Known rigid and semi-rigid orthoses and declinators, including those consisting of fabric corsets of various designs, inside of which are placed rigid inserts made of materials that allow the preliminary fitting of their geometric shape according to the figure [1-9].

The main disadvantage of these devices is that when they are worn due to stiff immobilization of the spine, the back muscles are deteriorated at the same time as vertebral pain decreases, therefore they are considered only as palliative drugs that increase the comfort of a person in the acute period and slightly improve the conditions for the regeneration of spinal tissues. To reduce the negative consequences of using corsets with rigid inserts, the duration of their continuous wear, as a rule, is limited to 3-4 hours a day.

Rigid lumbar-sacral and chest-lumbar-sacral corsets of the Boston system [10] are known, containing molded plastic plates formed according to the geometry of individual areas of the body and connected by flexible fasteners. In addition to the above-mentioned disadvantages, the screening of significant parts of the body by airtight materials, the restriction of respiratory excursions and motor activity are noted as negative characteristics.

Known plastic corsets of the Chenot type [11], made to order from thermoplastic materials, which allow for a metered effect on convex sections of deformed bone structures. When worn, the patient should be continuously in a plastic sleeve. Since these corsets are often used to correct scoliosis in children, its size should correspond to the dynamics of the growth and development of the child. This circumstance is the reason for the replacement of the corset at least 2 times a year, which is economically disadvantageous for the patient, given its cost. In addition, as with all other rigid corsets, it, with prolonged wear, helps to weaken the muscles of the abdominal belt and back, therefore, quite often after removing corsets of this type, negative dynamics of bone changes are observed.

Rigid corsets of the Milwaukee type [12] are known, consisting of a lower support in the form of plastic plates covering the upper and lateral regions of the ilium and a rigid frame attached to them with straps for individual tightening of the trunk to the rigid vertical frame supports. The main disadvantages of this design are the significant size of the support plates, the inability to put on the corset without assistance, the difficulty of dosing force corrective loads, and the limitation of motor activity.

Individually made rigid corsets are known [13], which are used for significant deformations of the spine, including traumatic origin, which also fully exhibits all of the above disadvantages.

Known interactive simulator-posture correctors that operate by the feedback mechanism [14]. When the indicators of the sensors located on the human body deviate beyond the range of acceptable boundaries with an incorrectly selected position, an alarm is triggered, which serves as a command for active conscious correction of the pose. The main disadvantage of these devices is the need for constant response to suddenly occurring signals and low efficiency with far-reaching postural disturbances.

Soft corsets are also known [2, 3, 11], which have higher performance properties, but their use in the presence of deformations of the bone structures of the upper half of the body is characterized by extremely low therapeutic and prophylactic effectiveness.

The closest solution to the proposed utility model is a reclinator for the treatment of deformity of the thoracic spine in the sagittal plane, containing an inflatable tire (shaper of the bends of the spine), fastened with straps to a rigid corset worn on the patient. The patient carries a declinator with a hose for supplying air to the inflatable tire along with the fastening system and corset [15]. The main disadvantage of this device is its low efficiency due to the fact that the patient has to constantly fix the spine on his own in the right position, pulling up the straps, since during operation, including when walking, the inflatable tire is displaced from the pain areas, as well as the structural rigidity that limits freedom of movement of the spine.

The purpose of the utility model is to increase the effectiveness of the corrective effect on the bones of the skeleton of the upper half of the body - the spinal column and shoulder girdle, to increase the therapeutic and prophylactic effect for back pain, spinal deformities and impaired posture, to increase the ease of use, as well as to expand indications for the use of the device.

The technical result, which consists in expanding the indications for the use of the device, improving the operational and consumer properties of the simulator-corrector, is ensured by the forced restoration of the anatomical bends of the spine and the position of the shoulder girdle by creating and automatically maintaining in the process of operation local pressure on pathologically altered convex bone structures according to a three-point pattern with maintaining free from external force impact of the opposite sunken area of the body In order to achieve a propping effect, dosed dynamic stretching (unloading) of the spine while preserving the degrees of freedom of natural movements of all the constituent parts of the musculoskeletal system, as well as forming, against the background of the normalized position of the spine and shoulder girdle, the muscular skeleton of the upper half of the body by performing muscular loads, weighed down by the creation of springy modules of additional mechanical resistance to spinal movements.

The stated goal is achieved by the fact that the dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle is made according to the modular principle in the form of structurally integrated elements in one device and contains a hygienic underwear knitted substrate to which a supporting pelvic girdle is attached from the bottom, containing a base in the form of a multilayer fabric panels with a width of at least 120 mm shorter along the upper edge compared to the lower edge with ends not attached to it at the ends There are less than 2 pairs of belts equipped with fabric fasteners adjustable along the grip length, while open and expanded pockets are sewn from the outside to the supporting pelvic girdle in the places of the supposed location of the cassette clips of the vertical flat spring modules, fabric containers with flat zig-shaped springs placed in them transversely in the thickness of the supporting pelvic girdle in individually variable locations, located in the pocket in the center of the supporting pelvic girdle of supports a platform made in the form of a plastic plate with three cassette clips of vertical flat spring modules rigidly fixed on it from the outside, mechanically adjustable in depth by a set of interchangeable interchangeable corrective inserts of various lengths placed inside, one of three cassette clips being placed in the center of the plate and two - on the edge, and on the inner side of the plate along the upper edge there is a shock absorber made of polyethylene foam with individually formed thickness, located in the side pockets of the supporting pelvic girdle an additional set of single cassette clamps of vertical flat springy modules, equipped with interchangeable interchangeable corrective inserts of various lengths placed inside, clamping straps of the support platform and separately located cassette clamps along the upper edge to the supporting pelvic girdle, a set of removable vertical flat spring modules made with unlimited freedom of bending in different directions in the form of continuous polymer strands, in the thickness of which are placed flat zig-shaped springs, a flat belt elastic collector with receivers for flat spring modules, equipped with a fabric fastener adjustable along the grip length, compensating elastic waist cushions located anterior to vertical flat spring modules with the possibilities of individual variation of their body contact area, thickness and location, compression belts of the lumbar and thoracic spine ika made with the possibility of individual variation of the efforts of pressing the body to the vertical flat springy modules. At the same time, a set of removable vertical flat springy modules is made in several sizes and versions according to the length, thickness of the spring wire, the width and the pitch of the bend of the spring as applied to individual age-related anthropometric characteristics and individual indications for correction with the possibility of additional independent mechanical individual adjustment of their length with a set of interchangeable interchangeable inserts of various lengths placed in cassette clips, and removable vertical According to indications, flat spring modules are additionally equipped with removable connecting cassette locks rigidly fixed at their upper ends.

In addition, according to indications, the device’s design also includes a shoulder girdle formed according to the actual dimensions with an allowance of at least 50 mm from the back side of a pair of removable shoulder flat plastic arcs equipped with axially adjustable armpits supporting straps with shock absorbers fixed on them, one or both the ends of each arc are rigidly connected by cassette locks to the upper ends of the respective vertical flat springy modules.

The structure of the design of the dynamic simulator-corrector additionally, according to indications, introduced a removable transverse flat spring module connected via polyethylene foam corrective gaskets with additionally extended rear central and rear lateral vertical flat spring modules, and the transverse flat spring module is made with the possibility of individually installing it in front or behind relative to the rear central vertical flat spring module and at the same time hydrochloric corrective modifications thickness polyethylene foam gaskets set of interchangeable inserts with the actual deformation of the thoracic spine and the state of the shoulder belt.

The power belt system additionally used according to indications, used in the design of the device, consists of a set of stretchable and non-stretchable load belts adjustable in length, connecting belt manifolds and fixed on belts in various positions of removable correcting pelots with interchangeable polyethylene foam inserts of various thicknesses and contact area with the body, load belts are configured to form individual temporary circuits articulated between each other and with by means of structural elements by means of connecting belt collectors and by varying attachment points of straps on a shoulder plastic arch supporting the pelvic girdle and on the rear lateral vertical flat springy modules so that the condition of creating a dosed local counterpressure on the convex areas of the bone structures of the upper half of the body according to the three-point pattern is maintained free from external force impact of the opposite sunken area of the body.

A comparative analysis of the claimed utility model with known technical solutions shows that it differs significantly in design by the possibility of integrated individual formation according to the actual readings of the parameters of local pressure on various areas of the bone structures of the upper half of the body, which provides for the forced restoration of the anatomical bends of the pathologically changed spine and the position of the shoulder girdle as well as subsequent automatic retention and individual dual correction during operation of the initially set parameters of local counterpressure to various areas of the upper half of the body and the efforts of traction of the spine using vertical and transverse flat spring modules, axillary belts, compression belts, power belt system, waist cushion, corrective inserts and corrective pilots, and the design allows, if necessary, to create traction loads of varying intensity on the right and left shoulders while maintaining in full about eme movement of all elements of the musculoskeletal system against the backdrop of the simultaneous mechanical stress on the back muscles and abdominals, which ensures the formation of the muscular frame of the upper half of the body in conditions burdened by the creation of additional mechanical stress the muscles in the background forcibly normalized biomechanical and anatomical characteristics of the spine and the position of the shoulder girdle. The presence of such properties opens up prospects for expanding the areas of use of the device both for restoring deformed posture and treating scoliosis, and for compensating the supporting functions of the spine in the postoperative period and for traumatic injuries, for eliminating vertebral pain and creating the prerequisites for eliminating intervertebral hernias.

At the same time, the possibility of self-donning and individual tightening of the supporting pelvic girdle, compression belts of the waist and chest sections of the spine, the power belt system and the lifting axillary belt, the individual installation and fastening of the shoulder plastic arches, the length of the vertical springy modules, including by replacing it with another set, the thickness of the compensating gaskets, corrective pilots, the thickness and location of the waist pads, as well as the position of the transverse flat uzhinistogo module under the control of subjective sensations enhances ease of use and effectiveness of the corrective influence, especially on the spine and shoulder girdle.

The mechanism of the corrective effect of the proposed device on the spine can be explained on the basis of an analysis of the patterns of formation of lordozo-kyphos-scoliotic deformities of the spinal column. According to modern concepts [16], the main reason for the formation of lordozo-kyphos-scoliotic deformities and back pain is the pathological rotation of a vertebra around the vertical or horizontal axes, including due to weakness, primarily of the tonic muscles, loss elastic properties of the pulpous nucleus, impaired integrity of the spinal disc, accompanied by protrusion of the pulpous nucleus (intervertebral hernias) or destruction of the vertebral body, degenerative-dystrophic and inflammatory processes in the joints. In this case, the vectors of elasticity and gravity acting along the spinal column change their direction and begin to act on the vertebrae at an angle that increases under load and (or) with age, leading to progression of deformations. With the progression of scoliosis, kyphosis or lordosis, the compression of the roots of the spinal cord at the places of their exit from the spinal column increases, contributing to the development of pain, the formation of myofascial blocks in the area of pathologically changed vertebrae, partial paresis of the musculature of the back, impaired reciprocal innervation and balance of muscle fibers of the post-tonic muscles that carry out the formation and maintenance of posture, often manifested by the formation of individually specific antalgic posture. If local counterpressure is carried out on the region of the spine, taking into account the deformation actually existing in a particular individual, then restoration of the physiologically adequate anatomical shape of the spine will lead to decompression of the nerve roots due to the gradual return to the initial state of all rotated vertebrae. The return of the rotated vertebrae to its original state will also be carried out because at the same time when using this device, dynamic traction of the spine, carried out by hanging the upper half of the body on the axillary belts of the shoulder arches, rigidly connected to vertical flat springy modules, creates the conditions for unloading the entire vertebral column and Against this background, muscle traction will gradually return pathologically rotated vertebrae to their original state, thereby reducing lordozo-kyphoso-scoliotic deformations. In this case, muscle training will also be observed, restoration of impaired reciprocal innervation, impaired muscle balance, decompression of nerve roots, reduction of pain and the creation of conditions for eliminating intervertebral hernias, which distinguishes the proposed device from all known designs.

The generalized positive effect of the use of this device, taking into account the mechanism of action discussed above, will be to reduce pain in the back, reduce and prevent lordozo-kyphos-scoliotic deformities, restore the integrity of vertebral discs and eliminate intervertebral hernias, restore the anatomical and physiological functions of the joints, and improve posture, increase activity and performance.

Thus, the data presented indicate that the proposed utility model meets the criteria of "novelty" and "non-obviousness." At the same time, the expected positive effects that can be achieved with its help, the availability of opportunities for technical implementation and the simplicity of organizing the operation of the proposed device, confirming the possibility of obtaining the results claimed for the purpose of the utility model, as well as the safety of its use, indicate that its criterion is “industrial necessity".

The device of the dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle is illustrated by the drawings:

Fig. 1 - General view of the simulator-corrector of the lumbar spine (Fig. A - front view; Fig. B - rear view);

Fig. 2 - General view of the simulator-corrector of the spine and shoulder girdle (Fig. A - front view; Fig. B - rear view);

Fig. 3 - General view of the supporting pelvic girdle;

Fig. 4 - General view of the support platform (Fig. A - front view; Fig. B - rear view);

Fig. 5 - General view of the single cassette clips of the vertical flat springy modules;

Fig. 6 - Vertical flat spring module assembled with a connecting cassette lock (side view in longitudinal section);

Fig. 7 - Lateral vertical flat spring module assembled with a shoulder flat plastic arc (side view in longitudinal section), transverse flat spring module and corrective gaskets (side view in cross section).

The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle, made according to the modular principle in the form of elements structurally integrated into one device (Fig. 1 - Fig. A and B, Fig. 2 - Fig. A and B) contains hygienic in static a wearable knitted backing 1, to which a supporting pelvic girdle 2 is attached from below, Fig. 3 containing a base 3 in the form of a multilayer cloth panel with a width of at least 120 mm shorter along the upper edge compared to the lower edge with attached to it at the ends of at least 2 pairs of belts 4, equipped with fabric fasteners adjustable along the grip length 5. Outside, open and extended upward pockets 6 are sewn to the supporting pelvic girdle 2, Fig. 3 at the locations of the proposed location of the cartridge clips 11, Fig. 4, 5 vertical flat springy modules 14. In the thickness of the supporting pelvic girdle 2, Fig. 3, fabric containers 7 are transversely arranged with flat zig-shaped springs 8 placed in them at individually variable locations. Located in pocket 6 in the center of the supporting pelvic girdle 2, Fig. 3, the supporting platform 9, Fig. 4, made in the form of a plastic plate 10 with three sets of interchangeable corrective inserts of various lengths mechanically adjustable in depth that are placed inside it and are mechanically adjustable in depth ( not shown) three cassette clips 11 vertical flat springy modules 14, one of which is located in the center and two on the edge of the plate 10, and on the inside of the plate 10 along the upper edge of the a shock absorber 12 made of polyethylene foam with an individually formed thickness is laid. An additional set of single cassette clips of Fig. 5 of vertical flat spring modules 14 is also placed in pockets 6 and equipped with interchangeable corrective inserts of various lengths placed inside (not shown).

The supporting platform 9 and separately located single cassette clips Fig. 5 along the upper edge are pressed against the supporting pelvic girdle 2 by pressure belts 13.

A set of removable vertical flat springy modules 14, Fig. 6 is made in the form of continuous polymer strands, in the thickness of which are placed flat zig-shaped springs 7, which provide the possibility of unlimited freedom of bending in different directions. To ensure individual adjustment, a set of removable vertical flat spring modules 14, Fig. 6 is made in several sizes and versions according to the thickness of the spring wire, the width and the pitch of the bend of the spring as applied to individual age-related anthropometric characteristics and individual readings with the possibility of additional independent mechanical individual adjustment of their length a set of inserts placed in cassette clips 11, Fig. 5 (not shown in the figure).

The upper ends of the vertical flat springy modules 14 are placed in the slit-like receivers of the flat belt elastic collector 15 equipped with a fabric fastener adjustable along the length of the grip. In addition, removable vertical flat springy modules 14, Fig. 6, additionally according to indications, are equipped with removable connecting cassette locks 16 that are rigidly fixed at their upper ends (Fig. 6).

Two removable shoulder flat plastic arc 17 (Fig. 7), formed by the actual size of the shoulder girdle with an allowance from the back of at least 50 mm, are equipped with axially adjustable axillary support belts 18 with shock absorbers 19 fixed to them, with one or both ends of each shoulder arc 17, Fig. 7 are rigidly connected by cassette locks 16 (Fig. 7) with the upper ends of the corresponding vertical flat spring modules 14 (Fig. 7).

A transverse flat spring module 20 (Fig. 7), the length of which corresponds to the individual width of the shoulder girdle, is located anterior to the lateral vertical flat spring modules (Fig. 2 Fig. B, Fig. 7) and is equipped with a fabric fastener that allows you to individually select its location along the length of the lateral vertical flat springy modules (not shown in the figure). In this case, the transverse flat spring module 20 (Fig. 7) is removable with the possibility of individual installation anterior or posterior to the rear central vertical flat spring module 20 (centrally located along the spine along the spine) (Fig. 7), the length of which is equal to the individual dimensions of the spinal column.

Corrective pads 21 with a set of interchangeable polyethylene liners of various thicknesses, selected taking into account the actual deformation of the thoracic spine and the condition of the shoulder girdle, are located in the area of contact between the rear side and rear central vertical flat spring modules 14 and the transverse flat spring module 20 (Fig. 2 Fig. B, Fig. 7).

Compensating elastic waist pads 22 (Fig. 1 Fig. B, Fig. 2 Fig. B), located anterior to the vertical flat springy modules 14, while their thickness and contact area with the body is selected individually using additional gaskets, and the location is by arbitrary fixing them on vertical flat springy modules 14 (not shown in the figure).

The compression belts of the waist 23 and thoracic 24 sections of the spine to create individual efforts to press the torso to the vertical flat springy modules 14 are equipped with a fabric fastener adjustable along the grip length (not shown in the figure), while the location of the compression belts is determined by arbitrary fixing them on vertical flat springy modules 14, for example, using an additional fabric fastener (not shown in the figure).

The power belt system (Fig. 2, Fig. A and B), consisting of a set of adjustable along the length of stretchable and not stretchable load belts 25, connecting belt manifolds 26 and fastened to belts in various positions of removable corrective pilots 27, adjustable in thickness and contact area with the body using interchangeable polyethylene foam liners. At the same time, the load belts 25 are interconnected by means of connecting belt manifolds 26 and varying by attachment points on the shoulder flat frame arc 17 supporting the pelvic girdle 2 and on the rear side vertical flat springy elastic modules (Fig. 7) so that the condition for creating a dosed local counterpressures on the convex areas of the bone structures of the upper half of the body according to a three-point pattern while maintaining the opposite sunken region free from external force I ate. The jointing of the load belts 25 among themselves is carried out according to temporary schemes using connecting belt collectors 26.

The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle works as follows.

To transfer the dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle, made according to the modular principle in the form of structurally combined elements in one device (Fig. 1-7), the following operations are performed sequentially.

1. Choose the appropriate size of the component elements of the device and the method of their installation in the device:

- hygienic underwear knitted substrate 1;

- a supporting pelvic girdle 2, Fig. 3, containing a base 3 in the form of a multilayer fabric with a width of at least 120 mm shorter along the upper edge compared to the lower edge with at least 2 pairs of belts 4 attached to it at the ends, equipped with adjustable along the grip length with fabric fasteners 5. When selecting a supporting pelvic girdle 2, Fig. 3, the locations of the external receiving pockets 6 for cassette clips 11, Fig. 4, 5 of the vertical flat spring modules 14 and the locations located in the thickness are also taken into account nogosloynogo cloth fabric container 7 placed therein zigoobraznymi flat springs 8;

- a support platform 9, Fig. 4, placed in the receiving pocket 6 in the center of the supporting pelvic girdle 2, Fig. 3, made in the form of a plastic plate 10 with three sets of interchangeable corrective inserts that are mechanically adjustable in depth and are fixed on the outside from the outside and placed inside it of various lengths (not shown in the figure) with three cassette clips 11 of the vertical flat springy modules 14, one of which is located in the center and two are located on the edge of the plate 10, and from the inside of the plate 10 along the upper edge It is made of a foam damper 12 individually formed thick;

- an additional set of single cassette clips of Fig. 5 vertical flat springy modules 14, placed in the receiving pockets 6 of the supporting pelvic girdle 2, Fig. 3 and equipped with interchangeable corrective inserts of various lengths placed inside (not shown);

- size and embodiment according to the thickness of the spring wire, the width and the pitch of the spring bend in relation to individual age-related anthropometric characteristics and individual readings of a set of removable vertical flat spring modules 14, Fig. 6, made in the form of continuous polymer strands, in the thickness of which are placed flat zig-shaped springs 7, providing the possibility of unlimited freedom of bending in various directions;

2. According to indications, removable connecting cassette locks 16 (Fig. 6) are rigidly fixed with screw clamps at the upper ends of the removable vertical flat spring modules 14, Fig. 6.

3. Insert the upper ends of the vertical flat springy modules 14 into the slit-like receivers of the flat belt elastic collector 15 equipped with a fabric fastener adjustable along the length of the grip.

4. According to the testimony, one or both ends of each shoulder flat plastic arc 17, Fig. 7, formed by the actual size of the shoulder girdle with an allowance from the back of at least 50 mm and equipped with axially adjustable axillary support belts 18 with shock absorbers 19 fixed to them, rigidly connect the cassette locks 16 (Fig. 7) with the upper ends of the corresponding vertical flat springy modules 14 (Fig. 7).

5. Based on the actual deformation of the thoracic spine and the condition of the shoulder girdle, a removable transverse flat spring module 20 (Fig. 7) is installed, the length of which corresponds to the individual width of the shoulder girdle anterior or posterior to the central vertical flat spring module, the length of which is selected equal to individual sizes vertebral column, and then select its location on the vertical flat springy modules 14, and fix it in this position using tissue tezhki.

6. Select the required thickness of the corrective gaskets 21 located in the contact area between the rear side and rear central vertical vertical spring modules 14 and the transverse spring plane module 20 (Fig. 2 Fig. B, Fig. 7), using a set of interchangeable polyethylene liners of various thicknesses taking into account the actual deformation of the thoracic spine and the condition of the shoulder girdle.

7. Put on the shoulders flat plastic arcs 17, Fig. 7.

8. Tightly tighten the pelvic support belt 2 using belts 4 equipped with fabric fasteners 5 adjustable along the grip length.

9. Additionally, if necessary, adjust the length of the right and left rear lateral vertical flat springy module, as well as the rear central vertical flat springy module by inserting inserts of the corresponding length inside the cassette clips Fig. 5.

10. Select the required thickness and contact area with the body of the compensating elastic waist pads 22 (Fig. 1 Fig. B, Fig. 2 Fig. B), located anterior to the vertical flat spring modules 14 and secured with a fabric fastener in the right place on the vertical flat spring modules 14.

11. Select the desired position of the compression belts of the lumbar 23 and thoracic 24 departments of the spine and fix them on a vertical flat springy modules 14 with a fabric fastener.

12. Tighten with the necessary force with the help of a fabric fastener adjustable along the grip length (not shown in the figure), compression belts of the waist 23 and thoracic 24 sections of the spine located around the torso to press the torso against the vertical flat springy modules 14.

13. Press the supporting platform 9 and the separately located single cassette clips Fig. 5 along the upper edge to the supporting pelvic girdle 2 with pressure straps 13.

14. The axillary supporting belts 18 with the shock absorbers 19 fixed on them, the fixation points of which are located at the beginning and at the end of the final rounding of the shoulder flat plastic arches 17 (Fig. 7), are pulled down by length-adjustable fasteners, according to the subjective feeling of the comfort of unloading the spinal column by hanging the body on axillary support belts 18.

15. The individual temporary structural schemes of the power belt system are formed according to individual indications (Fig. 2, Fig. A and B), for which they choose:

- type of load belts 25 (stretchable or non-stretchable);

- a method of articulating load belts 25 between each other through connecting belt collectors 26;

- a method of securing the load belts 25 in the attachment points located on the supporting pelvic girdle 2, as well as on the lateral vertical flat springy elastic modules 14 and on the shoulder flat plastic arches 17 (Fig. 7);

- thickness, contact surface area and location of removable corrective pilots 27 on the load belts 25.

16. Tighten the load belts 25 with a force at which a subjectively comfortable local counterpressure is felt on the convex areas of the bone structures of the upper half of the body in a three-point pattern while maintaining the opposite sunken area of the body free from external force.

17. The device thus prepared is ready for use.

If necessary, during operation, the user of this device itself can independently carry out, under the control of subjective feelings of comfort, additional correction of compression of the compression belts of the lumbar 23 and chest 24 of the spine, load belts 25 of the power system and axillary support belt 18.

As the state of the spinal column is restored, the location of the transverse flat springy module 20, as well as the thickness of the waist pads 22, corrective pads 21 and corrective pilots 27 can also be subjected to correction.

Specific examples of the use of the device.

According to generally accepted settings, the therapeutic effect of corset therapy is associated with the creation of local counterpressures on deformed bone structures according to a three-point pattern, while at the same time maintaining zones free of local pressure on concave parts of the body on the opposite side, as well as strengthening the spinal bearing capacity due to the use of supporting structures. However, the improvement in the condition of patients with scoliosis using modern rigid corsets of almost all types is temporary, and the achieved positive effects quite often disappear literally in the first 14 days after the end of treatment. Often after the cessation of wearing corsets, the disease progresses further. Meanwhile, rational corset therapy (orthosis) is still one of the most important components in the treatment and rehabilitation of patients with impaired posture and supporting spinal function, but using this method, doctors are forced to consider at least three circumstances:

- this method does not correct, but only slows down the progression of curvature of the spine;

- the effectiveness of the method is proportional to the exposure of its application, so it is advisable to wear a corset constantly and for a long time. However, all types of modern corsets with rigid support structures do not allow to realize this requirement due to side effects, among which one of the main ones is the training of torso muscles. In addition, treatment using corsets leads to a limitation of daily physical activity, which negatively affects the overall adaptive potential of the body;

- the cessation of wearing a corset due to the above features should be extremely balanced and consistent with the state of the post-tonic muscles at the time of its cancellation.

Meanwhile, a distinctive feature of the proposed design of the corset is the availability of continuous operation and carrying out, in such cases, corrective detorsion gymnastics, focused on training weakened muscle groups, including using special simulators, physiotherapy exercises and sports, which made it possible to increase the efficiency combined treatment at least 2 times compared with traditional methods of treatment. So, for example, in individuals with scoliosis of the I-II degree (13 people: 10 boys and 3 girls aged 13-17 years), an improvement in posture and a decrease in the arch of curvature of the spine was observed when using the combined treatment method using the proposed device in 100% cases, while according to our data (9 people: 7 boys and 2 girls aged 14-17 years), a similar healing effect using traditional treatment methods was found only in half of the examined patients, which coincides with the literature cheers. Simultaneous comparative control of muscle strength endurance at admission and after 2 months of wearing the proposed dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle showed an increase in strength endurance of the extensors of the back by 25% and the abdominal press by 30%, an increase in the range of motion in the spine 25% compared with traditional methods of treatment. Refusals from the use of a dynamic simulator-corrector were not observed in any case. The cessation of wearing the dynamic simulator-corrector was not accompanied by manifestations of discomfort, but at the same time, the habit of developing physical training developed during its wearing made it possible to ensure stabilization of the achieved positive effect after cessation of wearing it.

The therapeutic and prophylactic effectiveness of the device was tested on drivers of heavy vehicles engaged in intercity transportation. The experiments were attended by 19 drivers aged 30 to 50, complaining of back pain, fatigue, sleep disturbance, and gastrointestinal dysfunction. The experimental group, which used the proposed device in the process of driving cars, was formed in the amount of 11 people, and the control group was represented by 8 drivers. After 5-9 days, all the drivers included in the experimental group noted a noticeable improvement in their general condition and a decrease in severity, up to a complete refusal to present complaints. A follow-up survey of them a month later confirmed the presence of persistent positive effects, the main of which were improved performance, reduced fatigue by the end of the day, normalization of sleep, and the complete absence of back pain. Negative reviews related to the ease of use of the device were not presented. Almost all drivers expressed a request to purchase this device for permanent use. The condition of the drivers of the control group after 1 month remained almost unchanged, i.e. stably uncomfortable.

Thus, a comparison of the results confirms the effectiveness and feasibility of therapeutic and prophylactic use of the proposed device.

At the same time, the experience of the practical use of the dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle and the results of the analysis of the kinematic schemes of its functioning allows us to state that the proposed device almost completely meets the current requirements for an ideal corrector of violations of the supporting functions of the spinal column and posture. The functionally proposed simulator-corrector must have and actually has structural elements that allow:

- fix the bearing parts of the corset frame in the pelvic and shoulder girdles, without limiting the mobility of all elements of the musculoskeletal system;

- vary the composition, shape and position on the body of the load belts of the power system of local exposure;

- fix the position of the body in the sagittal plane;

- to form or restore physiological curves of the spine and posture;

- selectively apply local efforts according to the three-point scheme to the convex areas of the bone structures of the upper half of the body through supporting platforms of limited size, for example 200x200 mm, located on springy modules, compression belts and load belts of the power system, while leaving the opposite retracted parts of the body free from external influences ;

- perform a complex of corrective detorsion gymnastics exercises for narrowly focused training of weakened muscle groups, including using special simulators, physiotherapy exercises and play sports, creating an additional load on the muscles during body movements;

- to carry out, without limitation of movement, dosed hanging of the upper half of the body on axillary belts for unloading the spine;

- to form the mode of initial exposure, taking into account the individual characteristics of spinal deformities and postural disorders;

- carry out individual, including independent correction of local counterpressures on the bone structures of the upper half of the body during operation based on the results of medical observation and under the control of the dynamics of subjective sensations;

- carry out self-putting on and removing the device;

- carry out independent hygienic cleaning of the device using household products;

- eliminate the negative attitude to the product in terms of operational and aesthetic qualities.

The data presented confirm the feasibility of technical implementation, ensuring high operational characteristics, including ensuring safety and environmental friendliness of the application, simplicity of the organization of operation, as well as the achievement of therapeutic and prophylactic efficiency of the proposed device, and thereby indicate the attainability of the goals set during the development of the utility model.

SOURCES OF INFORMATION TAKEN INTO ACCOUNT WHEN DRAWING UP A DESCRIPTION FOR A USEFUL MODEL

1. Posture corrector ORLETT TLSO-250 (A) S: http://www.alteimark.ru/product-osanki-tlso-250a.

2. Posture Corrector: http://www.lysoform.ru/ortopedia/pozvonki.ru

3. Posture correctors (declinators): http://www.med-magazin.com.ua.

4. Patent RU N 2119312, cl. A61F 5/03, publ. 1998 year

5. Patent RU N 217070, cl. A61F 5/01, 5/03, publ. 2001 year

6. Patent 2234890, cl. A61F 5/02, publ. 2004 year

7. Patent 2223069, cl. A61F 5/02, publ. 2004 year

8. Patent 2170070, cl. A61F 5/01, publ. 2001 year

9. Corrective corset "PATTERN": http://www.ol-brace.ru/usore_br.htm

10. EMANS J.B., KAELIN A. et al. The Boston Bracing System for idiopathic scoliosis Spine, 1986, vol. 11, n 8.

11. Chenot type corset: http://www.ol-brace.ru/therapy.htm.

12. CAR W.A. et al. Treatment of idiopathic scoliosis in the Milwaukee brace. Bone and Joint Surgery (Am), 1980, vol. 62. P.p.559-612.

13. Individual tight corsets: http://pozvonotchnik.ru/corset2.html.

14. Interactive simulator-corrector: http://pozvonotchnik.ru/trainer2.html.

15. Copyright certificate SU N 645651, cl. 61F 5/02, publ. 1979 year

16. Zhulev N.M., Lobzin B.C., Badgaradze Yu.D. Manual and reflexology in vertebro-neurology. A guide for doctors. - St. Petersburg, 1992 .-- 589 p.

Claims (6)

1. A dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle, containing straps and fasteners, characterized in that it is made according to the modular principle in the form of structurally integrated elements in one device and contains a hygienic underwear knitted substrate, to which a supporting pelvic girdle is attached below containing a base in the form of a multilayer cloth panel with a width of at least 120 mm shorter along the upper edge compared to the lower edge with attached to at the ends of at least 2 pairs of belts equipped with fabric fasteners that are adjustable along the grip length, while open and expanded upward pockets are sewn to the supporting pelvic girdle at the places of the supposed location of the cassette clips of the vertical flat springy modules, fabric containers with flat ones placed in them zig-shaped springs located transversely in the thickness of the supporting pelvic girdle in individually varying locations, located in the pocket in the center of the supporting pelvis of the belt, a support platform made in the form of a plastic plate with three cassette clips of vertical flat springy modules rigidly fixed on it from the outside, mechanically adjustable in depth by a set of interchangeable interchangeable corrective inserts of various lengths placed inside, one of three cassette clips being placed in the center of the plate and two - along the edge, and on the inside of the plate along the upper edge there is a shock absorber made of polyethylene foam with an individually shaped thickness, located in the side pockets of the supporting pelvic girdle, an additional set of single cassette clips of vertical flat springy modules, equipped with interchangeable interchangeable corrective inserts of various lengths placed inside, clamping straps of the support platform and separately located cassette clamps along the upper edge to the supporting pelvic girdle, a set of removable vertical flat spring modules made with unlimited freedom of bending in different directions in the form of continuous polymer strands, in the thickness of which are placed flat zig-shaped springs, a flat belt elastic collector with slit-like receivers of flat spring modules, equipped with a fabric fastener adjustable along the grip length, compensating elastic waist cushions located anterior to the vertical flat spring modules with the possibility of individually varying their area of contact with the body, thickness and location, compression belts of waist and weight Foot spine adapted to the individual variation of the contact pressure of the body to the vertical flat springy modules. 2. The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle according to claim 1, characterized in that the set of removable vertical flat springy modules is made in several sizes and versions along the length, thickness of the spring wire, the width and pitch of the spring bend in relation to individual age-related anthropometric characteristics and individual indications for correction with the possibility of additional independent mechanical individual adjustment their lengths by a set of interchangeable interchangeable inserts of various lengths placed in cassette clips. 3. The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle according to claim 1, characterized in that the removable vertical flat spring modules are additionally equipped with removable connecting cassette locks rigidly fixed at their upper ends. 4. The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle according to claim 1, characterized in that it further comprises indications of a shoulder girdle formed by the actual dimensions of the shoulder girdle with an allowance from the back of at least 50 mm of a pair of removable shoulder plastic flat arches equipped with axially adjustable axillary support belts with shock absorbers fixed to them, while one or both ends of each arc are rigidly connected by cassette locks to the upper the ends of the corresponding vertical flat springy modules. 5. The dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle according to any one of claims 1 to 4, characterized in that it further comprises, according to the indications, a removable transverse flat spring module connected via polyethylene foam correction pads to the rear center and rear side additionally elongated vertical flat springy modules, and the transverse flat springy module is made with the possibility of individual installation in front of it and or behind the rear central vertical vertical springy module and the simultaneous modification of the thickness of the foam correction pads with a set of interchangeable inserts, taking into account the actual deformation of the thoracic spine and the condition of the shoulder girdle. 6. A dynamic simulator-corrector of the anatomical and biomechanical characteristics of the spine and shoulder girdle according to any one of claims 1 to 4, characterized in that it is additionally equipped with a power belt system consisting of a set of stretchable and non-stretchable loading belts, connecting belts collectors and fixed on belts in various positions of removable corrective pilots with interchangeable polyethylene foam inserts of various thicknesses and body contact area, at the same time, the load belts are made with the possibility of forming individual schemes of jointing with each other and with rigid structural elements by means of connecting belt manifolds and varying the belt attachment points on the shoulder plastic arc supporting the pelvic girdle and on the rear side vertical flat spring modules so that the condition for creating a dosed local counter-pressure on the convex areas of the bone structures of the upper half of the body according to a three-point pattern while maintaining free of external force action area opposite the hollow body.