RU2147826C1 - Method for diagnosing the cases of maxillodental anomaly - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves carrying out clinical examination and determining distances between diagnostic points on models of jaws and relations between them. Photographic pictures are used as dental models produced with digital camera. Dentition pictures are taken in frontal projection, from the right and from the left in central occlusion position as well as pictures of upper and lower dental arches in horizontal plane with mouth opened. EFFECT: enhanced reliability and accuracy of diagnosis; low consumption of materials; no imprints and diagnostic models needed. 2 cl, 5 dwg

Description

 The invention relates to medicine, dentistry, namely, orthodontics, orthopedics, oral and maxillofacial surgery, and can be used in the diagnosis of dentofacial anomalies and deformities.

 A known method for the diagnosis of dentoalveolar anomalies, including clinical examination and calculation of diagnostic models of the jaw (Persin LS Orthodontics. Diagnosis, types of dentoalveolar anomalies. - Moscow: Scientific and Publishing Center "ENGINEER", 1996). To identify the close position of the teeth, lack of space in the dentition, the degree of underdevelopment or hypertrophy of various departments of the dentition and alveolar parts, an analysis of diagnostic models of the jaw is necessary. Analysis of diagnostic models of the jaw is a mandatory step in the diagnosis and treatment planning of all orthodontic patients. Diagnosis of disorders of the dentoalveolar system according to the models consists in measuring the distances between specific tooth and skeletal points and comparing the obtained data with normal values. For the manufacture of diagnostic models of the jaws, it is necessary to obtain impressions of the upper and lower jaws. This procedure is carried out using standard impression trays and, as a rule, elastic alginate impression masses. It is known that taking casts not only takes time from the doctor, but also causes physical suffering to the patient, especially if it is a child. Often when taking impressions in children, a strong gag reflex is noted, which further serves as the basis for the formation of a negative attitude of the child to orthodontic treatment. The situation is aggravated by the fact that the removal of prints is sometimes necessary only for diagnosis, and not for the manufacture of an orthodontic apparatus. After taking impressions from the upper and lower jaws, the doctor casts the diagnostic models, prepares them for diagnosis, which also tears him away from direct contact with the patient. Impressions obtained by elastic impression masses, when models are not cast in time, decrease in size due to their shrinkage, which distorts the true clinical picture and can cause erroneous diagnostic conclusions.

 The disadvantage of this method is the need to take impressions, the tide of models, which requires not only serious time, but also material costs associated with the acquisition of expensive impression masses and super gypsum. To assess the dynamics of orthodontic treatment, certain storage conditions for cast models are required.

 The objective of the invention is to provide a method for the diagnosis of dentoalveolar anomalies, providing high diagnostic accuracy by eliminating errors caused by the deformation of casts of dentition and alveolar parts, with significant savings in time and materials.

 The problem is solved in that in the known method for the diagnosis of dentoalveolar anomalies, including clinical examination and determination of the distances between diagnostic points on jaw models and the relationships between them, according to the invention, photographic images of dentitions made by a digital camera with a focal length of less than 20 mm are used as models .

 The problem is also solved by the fact that they take pictures of the dentition in the central occlusion position in front, on the right and left sides, as well as photographs of the upper and lower dentition in the horizontal plane with an open mouth.

 The use of dental arches made by a digital camera with a focal length of less than 20 mm as models of photographic images ensures high diagnostic accuracy due to the fact that this camera allows high-quality shooting of small objects at close range (macro photography) with recording the results on a typical diskette, for example , format 3.5``. The use of this camera allows immediately after shooting to display the resulting photographs on a computer monitor and carry out their computer processing. Such models do not require significant storage space; the dynamics of treatment results can be easily estimated from them.

 For the most complete and qualitative assessment of dentoalveolar anomalies, it is advisable to take pictures of the dentition in the position of central occlusion in front, on the right and left sides, as well as photographs of the upper and lower dentition in a horizontal plane with an open mouth.

 In FIG. 1 shows a snapshot of dentitions in a central occlusion position in front; in FIG. 2 - a picture of the dentition in the position of the central occlusion on the right side; in FIG. 3 - a picture of the dentition in the position of the central occlusion on the left side; in FIG. 4 - a picture of the upper dentition in the horizontal plane; in FIG. 5 is a snapshot of the lower dentition in a horizontal plane.

 The method is as follows.

 All images are carried out using a standard rotator (lip retractor). A picture of the dentition in the central occlusion position in front is obtained when the camera is located at a convenient distance directly in front of the patient. The picture on the right side is obtained by positioning the camera to the right of the patient, pulling the labial retractor on the right side and loosening it on the left. A picture on the left side is obtained by positioning the camera to the left of the patient, pulling the labial retractor on the left side and loosening it on the right. A picture of the upper dentition in the horizontal plane is carried out using a metal mirror. In this case, the patient opens his mouth as much as possible, a mirror is inserted into the oral cavity and applied to the lower dentition. The upper dentition is completely displayed in the mirror. The image reflected in the mirror is taken. The shooting of the lower dentition, as well as the upper one, is carried out using a metal mirror. The patient opens his mouth as much as possible, a mirror is inserted into the oral cavity and pressed to the upper dentition. In this case, the lower dentition is displayed in the mirror. The image reflected in the mirror is taken. Pictures are recorded on a 3.5 '' floppy disk and transferred to a computer for subsequent diagnosis using the developed program. When photographing a real object, its dimensions obtained in the photo can differ significantly from the real ones. Therefore, the diagnostic program should enter the results of measurements of the parameters of the dentition and alveolar parts of the jaws in relative units, that is, in relation to the size of a pre-selected standardized object in the photograph. This allows you to take into account the change in the scale of objects in the photograph relative to real ones. During the shooting, it is necessary to measure the central incisors and the first molars, as well as the width of the apical bases of the upper and lower jaws. The latest data is entered into the program before measurements.

 In addition to this type of distortion of the dimensions of a real object in the photograph, there are also angular distortions — distortions of the dimensions of a real object when shooting it at an angle and distortions of perspective — a decrease in the sizes of real objects in the background of the photograph. A retrospective analysis of the diagnostic data by the above method for 108 patients with dentoalveolar anomalies showed that measuring and taking into account when calculating the opening angle of the mouth, the tilt of the optical axis of the camera lens to the mirror, and the tilt of the optical axis of the camera lens to the object being taken are not necessary, since the error introduced by them is comparable with instrumental.

 The method is illustrated by the following clinical example.

 Patient R. Age 12 years. Date of examination 5.12.98. Permanent bite. Photographs of the dentition were made with a SONY MVC FD-7 digital camera with a focal length of 4.2 to 42 mm (Fig. 1-5).

 Immediately prior to shooting in the patient’s mouth, a measuring compass measured the sizes of the right and left upper molars equal to 10.0 mm, the right and left lower molars equal to 10.5 mm, as well as the upper central incisors equal to 8.0 mm, and lower central incisors equal to 5.0 mm. In addition, we measured the width of the apical basis of the upper jaw in the fossae caninae region, equal to 30.0 mm, and the width of the apical basis of the lower jaw, departing 8 mm down from the intersection of the horizontal line connecting the necks of the canines and the first premolars with a vertical line passing through the top of their interdental gingival papilla, 36.0 mm. Before calculating diagnostic photographs, these data were entered into a computer.

 The calculation results are presented below.

 The sum of the width of the 4 upper incisors = 29.0 mm.

 The sum of the width of the 4 lower incisors = 21.2 mm.

 The sum of the width of the 12 upper teeth = 91.2 mm.

 The sum of the width of the 12 lower teeth = 82.6 mm.

 The length of the dentition of the upper jaw = 92.8 mm.

 The length of the dentition of the lower jaw = 83.4 mm.

 Deficit of space in the dentition of the upper jaw = -1.6 mm.

 Deficit of space in the dentition of the lower jaw = -0.8 mm.

 Transverse direction.

 The width of the dental arches (Pont).

 Narrowing of the dental arch in the region of molars in the upper jaw: I = 44.1 mm, N = 44.5 mm.

 Dental arch expansion in the area of molars in the lower jaw: I = 49.9 mm, N = 44.5 mm.

 Narrowing of the dental arch in the premolar region of the upper jaw: I = 31.0 mm, N = 34.0 mm.

 Narrowing of the dental arch in the premolar region of the lower jaw: I = 33.0 mm, N = 34.0 mm.

 Width of dental arches (Slabkovskaya).

 Narrowing of dental arches in the area of canines on the upper jaw: I = 30.1 mm, N = 30.4 mm.

 Expansion of dental arches in the area of canines on the lower jaw: I = 25.3 mm, N = 22.4 mm.

 Transversal and sagittal directions.

 Width and length of the apical base (Snagina).

 Expansion of the apical base of the lower jaw: I = 36.0 mm, N = 33.2 mm.

 The decrease in the length of the apical base of the lower jaw: I = 28.8 mm, N = 35.6 mm.

 Narrowing of the apical basis of the upper jaw: I = 30.0 mm, N = 40.0 mm.

 Narrowing of the apical basis of the upper jaw II degree (35%).

 A decrease in the length of the apical basis of the upper jaw: I = 27.1 mm, N = 35.4 mm.

 Sagittal direction.

 The length of the anterior segment of the dentition (Korghaus).

 Reduction of the anterior segment of the dentition of the upper jaw: I = 15.8 mm, N = 17.0 mm.

 Decrease in the anterior segment of the dentition of the lower jaw: I = 13.4 mm, N = 15.0 mm.

 The ratio of segments of the dental arches (Gerlach).

 Decrease in the anterior segment of the dentition of the upper jaw: I = 24.3 mm, N = 31.8 ± 0.3 mm.

 Decrease in the anterior segment of the dentition of the lower jaw: I = 20.4 mm, N = 30.5 ± 0.2 mm.

 An increase in the right segment of the dentition of the upper jaw: I = 29.7 mm, N = 22.5 ± 0.1 mm.

 An increase in the left segment of the dentition of the upper jaw: I = 29.1 mm, N = 22.5 ± 0.1 mm.

 Decrease in the right segment of the dentition of the lower jaw: I = 28.2 mm, N = 31.2 ± 0.2 mm.

 Reduction of the left segment of the dentition of the lower jaw: I = 28.0 mm, N = 31.2 ± 0.2 mm.

 The right segment of the dentition of the upper jaw is larger than the left: right I = 29.7 mm, left I = 29.1 mm.

 The right segment of the dentition of the lower jaw is larger than the left: right I = 28.2 mm, left I = 28.0 mm.

 The decrease in the length of the upper dentition: I = 91.2 mm, N = 96.6 ± 0.3 mm.

 The decrease in the length of the lower dentition: I = 82.6 mm, N = 92.9 ± 0.3 mm.

 The magnitude of the dental arches, their ratio (Weise).

 Narrowing of the dental arch of the upper jaw in the premolar region: I = 31.0 mm, N = 36.2 mm.

 Narrowing of the dental arch of the lower jaw in the premolar region: I = 33.0 mm, N = 36.2 mm.

 Narrowing of the dental arch of the upper jaw in the molars: I = 44.1 mm, N = 48.6 mm.

 Expansion of the dental arch of the lower jaw in the molars: I = 49.9 mm, N = 48.6 mm.

 Reducing the length of the anterior segment of the dentition of the upper jaw: I = 15.8 mm, N = 17.2 mm.

 Reducing the length of the anterior segment of the dentition of the lower jaw: I = 13.4 mm, N = 15.2 mm.

 Reducing the length of the right segment of the dentition of the upper jaw: I = 19.5 mm, N = 21.3 mm.

 Reducing the length of the left segment of the dentition of the upper jaw: I = 19.9 mm, N = 21.3 mm.

 Reducing the length of the right segment of the dentition of the lower jaw: I = 18.1 mm, N = 20.6 mm.

 Reducing the length of the left segment of the dentition of the lower jaw: I = 18.6 mm, N = 20.6 mm.

 The left segment of the dentition of the upper jaw is larger than the right: right I = 19.5 mm, left I = 19.9 mm.

 The left segment of the dentition of the lower jaw is larger than the right: right I = 18.1 mm, left I = 18.6 mm.

 For photographing dentitions and alveolar parts, it is possible to use not only a digital camera from SONY, where a 3.5 '' diskette is used as the storage medium, but also any other digital camera with a focal length of less than 20 mm, or with a large focal length, but supplemented by magnifying lenses fixed to the lens. The latter circumstance also allows you to shoot at close range.

 Tests of the proposed method for 7 months showed that its use allows you to completely abandon the taking of casts and the manufacture of diagnostic models, except when it is necessary to study the articulation ratios of the dentition in the articulator. The result of using the method is a significant saving in time and materials while improving the quality of diagnostics.

Claims (2)

 1. A method for the diagnosis of dentoalveolar anomalies, including clinical examination and determination of the distances between diagnostic points on the jaw models and the relationships between them, characterized in that the models are photographic images of the dentition made by a digital camera, and they take dentition images in the central occlusion position front, on the right and left sides, as well as pictures of the upper and lower dentition in the horizontal plane with an open mouth.  2. The method according to claim 1, characterized in that they use a digital camera with a focal length of less than 20 mm

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