RU2136209C1 - Method of detection of postural unbalance - Google Patents

Abstract

FIELD: medicine, particularly, physiological methods of examination of weight-bearing and locomotor system applicable in neurology, neurosurgery, orthopedics, traumatology and rehabilitation. SUBSTANCE: method includes registration of moire pattern successively in six periods of transfer of body weight to each foot from position of two-support state on balance. On bases if performed series of topograms, graphs of these transfers are constructed in three planes with subsequent assessment of degree of displacement of body axis. If it is found that body axis inclination in frontal plane to opposite side of supporting extremity amounts to 6 deg, and inclination forward in sagittal plane amounts from 0 to minus 4 deg, and in turning of body axis in horizontal plane it equals up to 4 dwg to same side, state of postural balance is stated, i.e., normal state of muscles ensuring vertical position of body. If inclination of body axis from vertical running through common weight center, in frontal plane is more than 6 dwg to opposite side of supporting extremity, or in inclination to same side; in sagittal plane in inclination forward through more than minus 4 dwg, or in inclination backward through more than 0.1 deg, or in horizontal plane in turning, through more than 4 dwg and minus 4 dwg, disturbance of postural balance (postural unbalance) is diagnosed. EFFECT: higher efficiency of diagnosis of disturbances of postural balance. 4 dwg, 3 tbl

Description

 The method relates to medicine, namely to physiological methods for the study of the musculoskeletal system (OA). It can be used in neurology, neurosurgery, orthopedics, traumatology, rehabilitation.

 In the process of its development, the body creates a system for ensuring the vertical position of the body due to the formation of physiological bends of the spine and postural muscle balance. The leading role in the implementation of this adaptive activity belongs to the muscles of the pelvic girdle, where the center of gravity of the body is located.

 In the brain, on the basis of proprioceptive afferentation, a vertical model of the body is created, the center of gravity of which must coincide with the sample. Only in this case will postural muscle balance be ensured in the vertical position of the body with minimal muscle costs. In case of a mismatch between the centers of gravity, a feedback correction is created in the control system of the ODE, which seeks to smooth out this discrepancy by expanding the stability area.

 In a normal state, the center of gravity of the body has vibrations in the sagittal plane, which is associated with the act of walking. The resulting kyphosis and lordosis increase the range of body vibrations with maximum stability in an upright position by expanding the area of stability. In the frontal plane, these fluctuations are not significant, therefore, the normal curvature of the spine in this plane are absent. Asymmetry, for example, in cervical-tonic reflexes, as a result of some pathological influences, causes a mismatch in the frontal plane of the simulated center of gravity and the real one. In order to ensure maximum stability of the body in the frontal plane in such a situation with minimal costs, the body seeks to increase the range of system stability due to the development of scoliosis. The exact same mechanism works as in the sagittal plane. The system seeks to increase the area of stability.

 When standing with an emphasis on one leg, the body weight shifts toward the supporting limb by 57.6 ± 7.0 mm towards the supporting limb.

 The total load on the limbs is estimated by the deviation of the biomechanical axis of the body from the vertical when standing, as it indirectly reflects the interaction of body weight and limb weight. By the magnitude of the deviation, one can judge the necessary degree of mobilization of various compensatory mechanisms and the real capabilities of the body. With large deviations, reserves can be quickly depleted and compensatory mechanisms are insufficient. Functional and then structural changes in ODE begin to develop.

 A known method for detecting postural imbalance by the method of podography, stabilization and plumb (Liebenson G. Rehabilitation of the Spine. 1996, Vasilyeva L. F. Visual diagnosis of violations of the statics and dynamics of human ODE. Ivanovo, 1996, pp. 9-14). Based on the change in the center of gravity during functional tests, the degree of participation of specific muscles in ensuring an upright position is estimated.

 The disadvantage of the prototype is that it evaluates only the movement of the projection of the center of gravity of the body. In what direction and to what extent the body has shifted in space in three planes, this method cannot indicate exactly.

The closest way to detect postural imbalance is computer optical topography for determining spinal deformities, developed at the Novosibirsk Scientific Research Institute of Optics and Siberian Scientific Research Institute of Optical Systems (traumatol. And orthopedic journal. 1994. 3. C. 43-51.). To convert information on the shape of the back surface into an image of an interferogram with phase encoding of measurement information in a topographer, the method of projecting strips with intersecting optical axes of the camera and projector is used
Initially, the moire pattern is recorded (Fig. 1) with three predetermined sections in the sagittal plane and four in the horizontal. Based on the mathematical processing, the angles of inclination of the body axis in three planes are calculated.

 FSD - frontal torso angle.

 SSD - sagittal torso angle.

 G Psis - rotation of the pelvis in the horizontal plane.

 This method is intended to detect signs of spinal deformity and are taken as a prototype. The disadvantage of the prototype is that the state of postural muscles is evaluated only in statics and does not allow to evaluate the participation of individual muscles in ensuring an upright position during any movement.

 The objective of the present invention is to increase the efficiency of diagnosis of disorders of the postural balance.

 The problem is achieved in that the registration of the moire pattern is carried out sequentially in six periods of transfer of body weight to each of the legs from the position of two-bearing standing on the scales. The obtained displacements of the body axis in each period and three planes are compiled into tables for each leg (Table 1).

Based on the data obtained, graphs are constructed (Fig. 2) of these movements in three planes, followed by an assessment of the degree of displacement of the body axis. When the body is tilted in the frontal plane in the opposite side of the supporting limb to 6 ^o , in the sagittal plane from 0 ^o to -4 ^o and in the horizontal to 4 in the same direction, the postural balance is judged, i.e. normal state of postural muscles to ensure the vertical position of the body. When the body axis is tilted from a vertical passing through the common center of mass in the frontal plane> 6 ^o to the opposite side of the supporting limb or tilted to the same side, in the sagittal plane when tilted forward> -4 ^o or tilted back> 0.1 ^o , in the horizontal plane> +4 ^o and -4 ^{o, a} violation of the postural balance is diagnosed.

 The essence of the method is as follows: The patient stands in front of the video camera in the two-support position on the scales and the moire pattern is recorded. Gradually transferring body weight to one of the legs, 6 topograms are carried out. Repeated on a tight leg. On the basis of the obtained data, tables of body movement in degrees in three planes are compiled. Using mathematical processing, the regularity of these movements is found and graphs are constructed. When analyzing these graphs, it is possible to accurately assess the degree of displacement of the body axis in three planes in any phase of the transfer of body weight to one of the legs, respectively, the increased activity or insufficiency of which muscles this provides.

 A graphical representation of the movement of the axis of the body allows us to evaluate the participation of individual muscles in ensuring postural balance when transferring body weight from a double-footed to a single-footed position and purposefully select a method for its correction.

Thus, from the data obtained in the graphs, it can be seen that when the body axis is tilted in the frontal plane in the opposite direction of the supporting limb to 6 ^o , when tilted forward in the sagittal plane from 0 ^o to -4 ^o , when the body axis is rotated in the horizontal plane to 4 ^o in the same direction they judge the state of the postural balance, i.e. the normal state of the muscles, ensuring the vertical position of the body.

When the body axis is tilted from a vertical passing through the common center of mass in the frontal plane> 6 ^o to the opposite side of the supporting limb or tilted to the same side, in the sagittal plane when tilted forward> - 4 ^o or tilted back> 0.1 ^o , in the horizontal plane when turning> +4 ^o and -4 ^{o, a} violation of the postural balance is diagnosed.

 Example 1. Patient "B" 37 years old, diagnosis: Lumbar osteochondrosis. Chronic relapsing course. Aggravation. Reflex pain syndrome on the left.

 A series of computer optical topography was produced, on the basis of which table 2 was compiled and graphs were constructed (Fig. 3).

When transferring body weight to the left leg (solid line in figure 3) in the frontal plane, oscillations of the body axis due to the instability of muscle tone, ensuring an upright position, are noted. In the sagittal plane - an inclination forward up to 6.5 ^o (N- up to 4 ^o ) due to the increased tone of the flexors of the body (mainly the ileo-lumbar). In the horizontal - at the first moment, the axis rotates counterclockwise by increasing the tone of the muscles that straighten the spine from the same side (iliac-lumbar, rotating on the left), then a sharp turn clockwise by 21.9 ^o (spasm of the same muscles on the right). At the end of the transfer of body weight, this entire cycle is repeated again, but to a lesser extent.

 When transferring body weight to the right leg (dashed line in Fig. 3), the body axis tilts to the right (normal to the left) and its significant fluctuations due to unstable muscle tone are noted in the frontal plane. At the end of the transfer of body weight, the correct slope is established (compensatory mechanisms are triggered). In the sagittal - in the initial and final phase, the axis tilts forward due to the increased tone of the flexors of the trunk, and in the middle - the deviation back (increased tone of the extensors of the back.). In the horizontal - a slight deviation of the axis counterclockwise at the beginning due to the increased initial tone of the rotors of the left body (straightening the spine, iliac-lumbar, rotating), then this is compensated by the inclusion of right-hand rotators.

 After analyzing the data obtained, we can conclude that against the background of increased tone of the square muscle on the right, both ileo-lumbar (pronounced on the left), which straighten and rotate the spine on the left, there is a violation of postural balance (imbalance), which is not adequate to the task.

 In connection with the obtained data on the state of the muscular system, an individual program for its recovery is planned, addressed to specific muscles.

 Example 2. "N" 34 years without complaints of the musculoskeletal system. Regularly engaged in fitness exercises.

 A series of computer optical topography was produced, on the basis of which table 3 was compiled and graphs were constructed (Fig. 4).

When transferring body weight to the left leg (solid line) in the frontal plane, the body axis deviates to the right to 3.7 ^o , in the sagittal plane - forward to 2.8 ^o , in the horizontal - counterclockwise to 1.8 ^o .

When transferring body weight to the right leg (dashed line) in the frontal plane, the body axis deviates to the left to 3.7 ^o , in the sagittal plane - forward to 1.9 ^o , in the horizontal - to 2 ^o clockwise.

 Based on the data obtained, it can be concluded that in this case, the tonic state of the muscles of the body provides postural balance (normal version).

Claims (1)

 A method for detecting postural imbalance based on optical topography using registration of the moire pattern of the back surface, characterized in that the registration of the moire pattern is performed sequentially in six periods of transfer of body weight to each leg from the two-position state on the scales, based on a series of topograms, graphs are built of these displacements in three planes with subsequent assessment of the degree of displacement of the body axis and when the body axis is tilted in the frontal plane in the opposite direction limb up to 6 °, when leaning forward in the sagittal plane from 0 to -4 °, when the body axis is rotated in the horizontal plane to 4 ° in the same direction, the state of postural balance is judged, i.e., the normal state of the muscles, ensuring the vertical position of the body and when the body axis is tilted from a vertical passing through the common center of mass in the frontal plane> 6 ° to the opposite side of the supporting limb or tilted to the same side, in the sagittal plane when tilted forward> -4 ° or tilted back> 0.1 ° in the horizon When turning> +4 and -4 °, a violation of the postural balance (postural imbalance) is diagnosed.

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