RU2177759C1 - Method for diagnosing state of dental bearing and holding apparatus - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves measuring tooth motility in time in moving it by applying controlled force. The controlled force is constant in magnitude. Tooth displacement velocity is measured at the stages of fast and slower linear changes of the tooth motion velocity. Fast linear change of tooth motion velocity increasing relative to a reference value, tissue inflammation in anchoring holding apparatus of tooth. The slower linear change of tooth motion velocity increasing relative to a reference value, reduction of periodontium area. The controlled force being equal to 200 g and fast linear displacement of tooth being greater than 3.1 mcm/s, tissue inflammation is to be diagnosed. Slower changes of tooth motion velocity being greater than 0.03 mcm/s, reduced periodontium area is to be diagnosed. EFFECT: increased reliability of express-evaluation. 3 dwg

Description

 The invention relates to dentistry and can be used in the diagnosis of the condition of tissues of the supporting-restraining apparatus of the tooth.

 There are many ways to measure tooth mobility. Their action is based on the mechanical, optical, electronic principle [1], [2], [3], [4].

 In known methods, the measurement of mobility is carried out by moving the tooth with a dosed force and the magnitude of this movement is fixed. At the same time, a large scatter of tooth mobility indicators is obtained with a relative physiological norm of 31 μm to 110 μm, which is associated with different forces applied to the tooth (loads from 100 g to 700 g). With an increase in tooth mobility relative to the physiological norm, a violation of the state of the tissues of the musculoskeletal system is diagnosed.

 However, in all these technical solutions when measuring tooth mobility, the time of the force itself is not recorded, and they also do not determine how the tooth displacement depends on the time of the force.

 A limitation of the known technical solutions is the impossibility of diagnosing the specific nature of violations of the supporting-retaining apparatus of the tooth.

 A known method for diagnosing the condition of the support-holding apparatus of the tooth, including measuring mobility by moving the tooth with a dosed force and fixing the magnitude of this movement, and diagnosing the disease by measured mobility [5].

 In this method, a metered hit is additionally applied to the tooth, the parameters of which are determined depending on the root area, at the moment of impact, the average amplitude of the load deflection, which continues to move by inertia, is recorded, and the amplitude is calibrated for statistical force, and the degree of mobility is determined by the formula through statistical force and amount of work when moving a tooth. The method allows to increase the accuracy of data on the intensity of resorption-restoration processes in the periodontium of teeth.

 The limitations of this method are the impossibility of diagnosing the specific nature of disorders of the supporting-restraining apparatus of the tooth; low reliability of the results obtained, since the parameters of a metered blow are determined depending on the root area; complexity of implementation.

 The closest is a method for diagnosing the condition of the support-holding apparatus of the tooth, including measuring the change in mobility over time by moving the tooth with a dosed force and fixing the magnitude of this movement, and diagnosing the disease by measured mobility [6].

 The method described in this source of information uses a metered force that increases in time with loads from 30 g (in the time interval ≈ 1 s) to 120 g (in the time interval ≈ 3 s) to move. After that, the dosed increasing force is removed from the tooth and the character of the tooth returning to its initial position is observed. The nature of the dependence of mobility on time in the first and second phases of increasing mobility with increasing force, as well as in the third and fourth phases of decreasing mobility in the absence of load on the tooth, is examined. By the nature of the decaying dependence of tooth movement on time in the fourth phase, if it is higher than a similar curve for a tooth in physiological norm and has a stepwise, rather than smoothly decaying character, they judge the presence of a disease - periodontosis. An increase in tooth movement in time with the application of increasing force in the first and second phases in comparison with a similar curve for a tooth in physiological norm indicates a violation of the state of the support-holding apparatus of the tooth, but does not allow to diagnose the nature of these disorders, since the curve of the dependence of tooth movement in time at application of increasing force has a smoothly increasing characteristic close to linear.

 The limitations of this method are the impossibility of diagnosing the specific nature of violations of the supporting-retaining apparatus of the tooth in the first two phases of increasing the speed of movement of the tooth; low reliability of the results obtained, since an increase in tooth mobility compared to a tooth in physiological norm can occur from completely different factors.

 The problem solved by the invention is the expansion of the functionality and arsenal of means for diagnosing the specific nature of disorders of the musculoskeletal system of the tooth, increasing the reliability of the results and the rapid assessment of the state of the musculoskeletal system of tooth tissues.

 The technical result that can be obtained by implementing the method is the provision of diagnostics for decreasing the periodontal area and diagnosing tissue inflammation in the supporting and retaining apparatus of the tooth.

 To solve the problem with achieving a technical result in the known method for diagnosing the condition of the supporting-retaining apparatus of the tooth, including measuring the change in mobility over time by moving the tooth with a measured force and fixing the magnitude of this movement, and diagnosing the disease according to the measured mobility, according to the invention, a constant is used to move the tooth the largest dosed force, when measuring the change in mobility over time, the speed of movement of the tooth is fixed and when When the tooth movement speed is measured, the phases of a fast linear change in the tooth movement speed and a slower change in the tooth movement speed are detected, a quick linear change in the tooth movement speed is compared with a fast linear change in the tooth movement speed in the physiological norm, and when it increases, the inflammation of the tissues in the tooth supporting and holding apparatus is diagnosed , compare the slow change in the speed of movement of the tooth with the slow change in the speed of movement of the tooth in the physiological norm and at growth is diagnosed with a decrease in periodontal area.

Additional embodiments of the method are possible, in which it is advisable that
- the dosed strength was selected at a tooth load of 200 g;
- a quick linear change in the speed of tooth movement in the physiological norm was taken equal to 2.8 μm / s;
- a quick linear change in the speed of movement of the tooth during inflammation of the tissues in the supporting and retaining apparatus of the tooth was taken to be greater than 3.1 μm / s;
- a slow change in the speed of tooth movement in the physiological norm was taken equal to 0.024 μm / s;
- a slow change in the speed of movement of the tooth with decreasing periodontal area was taken to be greater than 0.03 μm / s.

 These advantages, as well as features of the present invention are illustrated by the best options for its implementation with reference to the drawings.

FIG. 1 depicts the dependence of the movement of the canine and incisor on time with a dosed force in physiological norm;
FIG. 2 - the dependence of tooth movement on time with a dosed force in the physiological norm and with a decrease in the periodontal area;
FIG. 3 - dependences of tooth movement on time with dosed strength in the physiological norm and with tissue inflammation.

 To implement the inventive method, you can use various known devices for measuring tooth mobility. However, it is recommended to use constant dosed forces at loads of not more than 200 g (mainly from 75 g to 200 g) to obtain more accurate results and undistorted data, as well as to avoid injuring a healthy tooth.

 To implement the method, a specially made device was used. The basis of the device is a mechanical indicator with a division price of 2 microns, mounted on an arc. The arch is fixedly mounted on the dentition, for example, the lower jaw. The mechanical indicator is positioned so that the dental probe is at the level of the cutting edge of the tooth under study. The load on the tooth is applied with weights from 75 g to 200 g. The weight is attached to the cable, on the other end of which a loop is made that fits over the tooth. The cable itself passes through a rotating axis, which is fixed on the device, forming a block. The time of application of the dosed force applied to the tooth using the block described above is fixed by a stopwatch, and after a certain number of seconds the tooth is returned to its original position. Then, the tooth movement is fixed with a stopwatch for the next fixed period of time, the load is removed, returning the tooth to its original position, etc.

 A method for diagnosing the condition of a support-holding apparatus of a tooth includes measuring the change in mobility over time by moving the tooth with a dosed force and fixing the magnitude of this movement.

 When measuring mobility, the speed of movement of the tooth is recorded. As was established during measurements, for a constant load, the curve of the dependence of displacement on time has two pronounced phases with an inflection point on the characteristic. The first phase lasts quickly, and the tooth shifts by a significant amount (Fig. 1). The second phase lasts more slowly, and the tooth moves by a much smaller amount. Thus, the phases of a fast linear change in the speed of movement of the tooth and a slower change in the speed of movement of the tooth are revealed. A quick linear change in the speed of tooth movement is compared with a fast linear change in the speed of tooth movement in the physiological norm, and when it is increased, inflammation of the tissues in the support-holding apparatus of the tooth is diagnosed (Fig. 3). In addition, a slow change in the speed of tooth movement is compared with a slow change in the speed of tooth movement in the physiological norm, and when it increases, a decrease in the periodontal area is diagnosed (Fig. 2).

 It is known that the tooth is located in the jaw bone and is attached to it with the help of a periodontium. In relative physiological norm, the root of the tooth is immersed in the bone almost completely. The thickness of the periodontium is from 0.15 to 0.35 mm. Therefore, the tooth has physiological mobility (Fig. 1), which is slightly different for the canine and incisor.

 With age and with periodontal disease, bone atrophy occurs and, as a result, tooth mobility increases. Tooth mobility can also increase with traumatic overload and inflammation of the tissues surrounding the tooth. Sometimes these processes are closely related. Therefore, to date, it has been quite difficult to find out the reason for the increase in tooth mobility and conduct differential diagnostics. However, the claimed method allows for such a diagnosis.

 Indeed, let us consider the movements of the lower second incisor with a periodontium in the relative physiological norm at a load of 200 g (Fig. 1). The movement of the second incisor can be divided into two phases. In the first phase, which lasts 5 s, a significant tooth displacement of 14 μm occurs. The speed of tooth movement in the first phase is 2.8 μm / s. When a load is applied to the tooth, the tension of the periodontal fibers occurs, which in a relative physiological rest is in a relaxed state. Since periodontal fibers have high elasticity, their elongation is proportional to the applied force (Hooke's law). Therefore, the tooth displacement in the first phase is linear. After reaching a certain degree of deformation of periodontal fibers with a dosed force acting on the tooth, the second phase of tooth movement begins.

 The second phase of the movement of the second incisor in this case lasts 295 s. In this phase, the movement of the tooth is only 7 microns. The speed of tooth movement in this phase is 0.024 μm / s. In this case, the nature of tooth displacement changes: the curve has a nonlinear kink, and then it is close to linear. This behavior of the tooth is associated not only with further deformation of periodontal fibers, but also with the flow of the liquid contents of the periodontium and its filtration between periodontal fibers.

 From this we can conclude that periodontium has a pronounced viscosity. Moreover, the viscosity is proportional to the periodontal area. Cutters with a small periodontal area have the lowest viscosity. In canines with a larger periodontal area, the viscosity is higher (Fig. 1). When a load is applied to a canine with a periodontium, a relative physiological norm shows a decrease in its mobility mainly due to a change in the second phase (Fig. 1). This is due to the higher viscosity of its periodontal.

 To identify pathological conditions of the musculoskeletal system of the tooth, a comparison of changes in the speed of movement of the tooth relative to the physiological norm is used.

 Resorption of the bone of the hole in which the tooth is located leads to a decrease in the periodontal area. Since the tissue of the remaining periodontium itself does not change, the character of tooth displacement in the first phase will be the same as in the physiological norm (Fig. 2). The speed of tooth movement in the first phase does not change compared to the norm, and the amount of movement in this phase also does not change. A significant increase in tooth mobility occurs in the second phase, since its viscosity decreases due to a decrease in the periodontal area. The speed of tooth movement in the second phase for the considered example is 0.092 μm / s. The speed of tooth movement in physiological norm is 0.024 μm / s. Therefore, the speed of tooth movement increases by more than 2 times. The method itself allows you to track very small changes in speed. Studies have shown that if a slow change in the speed of tooth movement has a value greater than 0.03 μm / s, then it is already possible to diagnose a decrease in periodontal area. However, usually during the resorption of the bone of the hole in which the tooth is located, the speed of tooth movement in the second phase increases by more than 1.5 times, therefore, the method can be used for rapid assessment of the periodontal condition of the tooth.

 An increase in tooth mobility may be a symptom of another common pathology - inflammation in the musculoskeletal system. This is accompanied by an increase in periodontal gap and swelling of periodontal fibers. The increase in overall tooth mobility occurs due to the first phase, which leads to a change in the nature of tooth movement (Fig. 3). The rate of increase in displacement in the first phase is 6.8 μm / s, which is two times higher than the physiological norm. Since the periodontal area remains the same, the viscosity is practically unchanged. Therefore, the nature of tooth movement in the second phase will be the same. As studies have shown, if a quick linear change in the speed of movement of the tooth has a value greater than 3.1 μm / s, then it is already possible to diagnose tissue inflammation in the supporting-retention apparatus. However, usually the speed of tooth movement in the first phase increases by more than 1.4 times, so the method can also be used for rapid assessment of the state of tooth tissue.

 Thus, by measuring the speed of tooth movement during the first (5 s) and second phases (295 s) of tooth movement at a dosed constant, the processes occurring in the periodontium can be diagnosed by the magnitude of the force. It should be noted that tooth movement in the second phase is slow and at the end of measurements it is close to linear. Therefore, it is possible, when implementing the method, to reduce the total time for measuring tooth mobility to 120 s, which already makes it possible to identify various types of pathologies.

 It is clear that the phases of fast and slow movement described above upon application of loads other than 200 g will have only other speeds.

 Examples of the method.

 Example 1

 To characterize the physiological norm, the experiment was carried out on the second incisor and second canine of the lower jaw in 48 volunteers aged 20 to 33 years with a periodontium in the relative physiological norm. The load on the tooth was applied with weights of 200 g. Previously, the spring force of the mechanical indicator was compensated by hanging weights of 120 g. The tooth displacement was determined after 5, 30, 60, 120, 180, 240, 300 s. It was found that the values of the speeds in the first and second phases differ for teeth in the physiological norm of various people in the range up to 4%.

 Example 2

 Patient B. During rapid diagnosis, carried out in accordance with the claimed method, it was established in the first phase an increase in the rapid linear change in the speed of movement of the tooth (Fig. 3) relative to the physiological norm. Further studies carried out by known means and methods confirmed an increase in the periodontal gap and swelling of the periodontal fibers.

 Example 3

 Patient K. During rapid diagnosis, an increase in the second phase of a slow change in the speed of movement of the tooth (Fig. 2) relative to the physiological norm was established. Further studies carried out by known means and methods confirmed a decrease in periodontal area as a result of bone resorption.

 Example 4

 Patient X. During express diagnostics, an increase in the speed of tooth movement in the first and second phase was established relative to the physiological norm. Further studies carried out by known means and methods confirmed a decrease in the periodontal area, as well as an increase in the periodontal gap.

 The most successfully claimed method for diagnosing the condition of the supporting and retaining apparatus of the tooth is industrially applicable in dentistry to expand the functionality and arsenal of differential diagnostics of the nature of violations of the supporting and retaining apparatus of the tooth and to carry out an express assessment of the state of the supporting and retaining apparatus of tooth tissues.

Sources of information
1. Oka H., t. Yamamoto, K. Saratani, T. Kawazoe. Automatic diagnosis system of tooth mobility for clinical use. Med, Prog. Technology 1990, N16, 117-124.

 2. Ryden H., Bjelkhagen H., Soder P. —O. Movement of healthy and periodontally involved teeth measured with laser reflection technique. J. Periodontol, 1982, N 53, 439-445.

 3. Niedermeier W. Parameters of tooth mobility in cases of normal function and functional disorders of the masticatory system. J. Oral Rehabili. 1993, N 20, 189-202.

 4. Patent of the Russian Federation 2068242, A 61 C 19/04, publ. 1996 year

 5. Copyright certificate of the USSR 874051, A 61 C 19/04, publ. 1981

 6. US patent 4058115, A 61 B 5/10, publ. 1977

Claims (2)

 1. A method for diagnosing the condition of the support-holding apparatus of a tooth, including measuring the change in tooth mobility over time by moving it with a dosed force and fixing the magnitude of this movement, characterized in that a constant dosed force is used, the speed of the tooth is determined in phases of fast and slower linear changes in the speed of movement of the tooth and with an increase in the rapid linear change in the speed of movement of the tooth relative to the norm diagnose inflammation of tissues in the supporting o-retaining apparatus of the tooth, and with an increase in the slow change in the speed of movement of the tooth relative to the norm, a decrease in the periodontal area is diagnosed.  2. The method according to p. 1, characterized in that with a measured dose of 200 g and a quick linear tooth movement of more than 3.1 μm / s, tissue inflammation is diagnosed, and with a slow change in tooth movement speed of more than 0.03 μm / s - decrease in periodontal area.

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