RU146649U1 - DENTAL BIOMETRIC PATTERN OF PARILOV - Google Patents

Abstract

The utility model relates to dentistry and can be used to measure the dentofacial system in a spatial coordinate system to recreate the anatomical shape of the dentition in the manufacture and installation of artificial teeth.

The dento-maxillary biometric pattern consists of a flat plate 1 of a parabolic shape made of transparent organic glass, on which the Cartesian coordinate system with transversal 2 and sagittal 3 coordinate axes is marked.

The marking on the pattern of the surface of the lower jaw 4 of Fig. 3 is made with a contact point 5 for aligning with the central incisors 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw of the gypsum model along the sagittal axis 3, 6 of the top of the tubercles of the tooth 33 (left half of the lower jaw, 3 is the canine) and tooth 43 (of the right half of the lower jaw, 3 is the canine), 7 of the top of the buccal tubercles of the tooth 34 (left half of the lower jaw, 4 - the first premolar) and tooth 44 (the right half of the lower jaw, 4 - the first premolar), 8 in rhinitis of the buccal tubercles of the tooth 35 (left half of the lower jaw, 5 - the second premolar) and tooth 45 (the right half of the lower jaw, 5 - the second premolar), 9 vertices of the medial buccal tubercles of the tooth 36 (left half of the lower jaw, 6 - the first molar) and tooth 46 (the right half of the lower jaw 6 - the first molar), 10 vertices of the distal buccal tubercles of the tooth 36 (the left half of the lower jaw, 6 - the first molar) and tooth 46 (the right half of the lower jaw, 6 - the first molar), 11 vertices of the medial buccal tubercles of the tooth 37 (the left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half the lower jaw, 7 - the second molar), 12 vertices of the distal buccal tubercles of the tooth 37 (the left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar), 13 vertices of the lingual tubercles of the tooth 34 (left half of the lower jaw, 4 - the first premolar) and tooth 44 (the right half of the lower jaw, 4 - the first premolar), 14 vertices of the lingual tubercles of the tooth 35 (the left half of the lower jaw, 5 - the second premolar) and tooth 45 (the right half of the lower jaw, 5 - the second premolar), 15 vertices of the medial lingual tubercles of the tooth 36 (the left half of the lower jaw, 6 - the first th molar) and tooth 46 (the right half of the lower jaw, 6 - the first molar), 16 vertices of the distal lingual tubercles of the tooth 36 (left half of the lower jaw, 6 - the first molar) and tooth 46 (right half of the lower jaw, 6 - the first molar) , 17 vertices of the medial lingual tubercles of the tooth 37 (the left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar), 18 vertices of the distal lingual tubercles of the tooth 37 (left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar).

The marking on the pattern of the surface of the upper jaw 19 of Fig. 4 is made with a contact point 20 for aligning with the central incisors 11 teeth (the right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw gypsum model along the sagittal axis 3, 21 vertices of the tubercles of tooth 13 (right half of the upper jaw, 3 canine) and tooth 23 (left half of the upper jaw, 3 canine), 22 vertices of the buccal tubercles of tooth 14 (right half of the upper jaw, 4 - the first premolar) and tooth 24 (the left half of the upper jaw, 4 - the first pr molar), 23 vertices of the buccal tubercles of tooth 15 (the right half of the upper jaw, 5 - the second premolar) and tooth 25 (the left half of the upper jaw, 5 - the second premolar), 24 vertices of the medial buccal tubercles of the tooth 16 (right half of the upper jaw, 6 - the first molar) and tooth 26 (left half of the upper jaw, 6 - the first molar), 25 tops of the distal buccal tubercles of tooth 16 (right half of the upper jaw, 6 - first molar) and tooth 26 (left half of the upper jaw, 6 - first molar) , 26 tops of the medial buccal tubercles of the tooth 17 (the right half of the upper jaw, 7 - the second molar) and a 27 (left half of the upper jaw, 7 - the second molar), 27 tops of the distal buccal tubercles of tooth 17 (the right half of the upper jaw, 7 - the second molar) and tooth 27 (left half of the upper jaw, 7 - the second molar), 28 vertices of the palatine tubercles of tooth 14 (right half of the upper jaw, 4 - first premolar) and tooth 24 (left half of the upper jaw, 4 - first premolar), 29 vertices of the palatine hillocks of tooth 15 (right half of the upper jaw, 5 - second premolar) and tooth 25 ( the left half of the upper jaw, 5 - the second premolar), 30 vertices of the medial palatine tubercles of the tooth 16 (right sexes on the upper jaw, 6 - the first molar) and tooth 26 (the left half of the upper jaw, 6 - the first molar) 31 tops of the distal palatine hillocks of the tooth 16 (the right half of the upper jaw, 6 - the first molar) and tooth 26 (the left half of the upper jaw 6 - the first molar), 32 vertices of the medial palatine tubercles of tooth 17 (the right half of the upper jaw, 7 - the second molar) and tooth 27 (the left half of the upper jaw, 7 - the second molar), 33 vertices of the distal palatine tubercles of the tooth 17 (right half of the upper jaw 7 - the second molar), and tooth 27 (the left half of the upper jaw, 7 - the second molar).

The technical result of the claimed biometric patterns is that it allows to simplify the exact reconstruction of dental arches, teeth, their anatomical shape and the location of the tubercles of the teeth in relation to the temporomandibular joint and chewing muscles, which is important for the function of movement of the lower jaw.

The inventive pattern is used in the educational process when performing educational research and practical work in studying the structure and position of the teeth, their relationship to each other. The proposed pattern helps to master the scientific and practical basis of the anatomy of the dentition and improve the quality of dental care.

1 P.F., 4 ill.

Description

The utility model relates to dentistry and can be used to measure the dentofacial system in a spatial coordinate system to recreate the anatomical shape of the dentition in the manufacture and installation of artificial teeth.

The closest technical solution is a dentofacial biometric pattern containing a spherical convex plate made of transparent organic glass with a marking of the Cartesian coordinate system with transverse and sagittal coordinate axes. The plate is made parabolic in shape corresponding to the geometric similarity of the dental arches. On the surface of the plate, markings are made corresponding to the geometric arrangement of the dental arches according to the most common sizes. (RF patent No. 63214, M. Cl. A61C 19/04, 2006)

The disadvantages of the known biometric patterns are the inability to recreate the reliable shape of the dentition, dental arches, anatomical shape and location of artificial teeth.

The objective of the proposed utility model is to create a dentofacial biometric pattern with high measurement accuracy and the correct spatial arrangement of artificial teeth with normal chewing function.

The task is achieved by the fact that in the dentofacial biometric piece containing a parabolic plate made of transparent organic glass with a Cartesian marking system with transverse and sagittal coordinate axes, the new one is that the lower jaw was marked on the outer surface of the flat plate, and the upper jaw was marked on the opposite surface of the plate, the marking of each vertex of the tubercles of the tooth 33 (the left half of the lower jaw, 3 is the canine) and tooth 43 (the right half of the lower jaw, 3 is the canine) made at a distance of 14 mm along the transversal coordinate axis and at an angle of 90 ° to the sagittal axis at a distance of 5.2 mm from the contact point for alignment with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, marking each vertex of the buccal and lingual tubercles of the tooth 34 (the left half of the lower jaw, 4 - the first premolar) and tooth 44 (the right half of the lower jaw, 4 - the first premolar ) made at a distance of 17.6 mm transverse axis and at an angle of 48.1 ° to the sagittal axis at a distance of 9.5 mm from the contact point for alignment with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, the marking of each vertex of the buccal and lingual tubercles of the tooth 35 (the left half of the lower jaw, 5 is the second premolar) and tooth 45 (the right half of the lower jaw, 5 is the second premolar) , 5 mm along the transversal axis and at an angle of 73.4 ° to the sagittal axis at a distance 16.5 mm from the contact point to align with the central incisors 31 teeth (left half of the lower jaw, 1 - first incisor) and 41 teeth (right half of the lower jaw, 1 - first incisor) of the lower jaw on the gypsum model along this axis, marking each vertex of the medial buccal and lingual tubercles of the tooth 36 (the left half of the lower jaw, 6 is the first molar) and the tooth 46 (the right half of the lower jaw, 6 is the first molar) is made at a distance of 23.2 mm along the transverse axis and at an angle of 69.8 ° to the sagittal axis at a distance of 22.6 mm from the contact point for combination with prices incisors 31 teeth (left half of the lower jaw, 1 - the first incisor) and tooth 41 (right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, marking each vertex of the distal buccal and lingual tubercles of the tooth 36 (left half of the lower jaw, 6 - the first molar) and tooth 46 (the right half of the lower jaw, 6 - the first molar) is made at a distance of 25 mm along the transverse axis and at an angle of 59 ° to the sagittal axis at a distance of 27.5 mm from the contact point for alignment with central incisors of 31 teeth (left half of the lower jaw and, 1 - the first incisor) and 41 teeth (the right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, the marking of each vertex of the medial buccal and lingual tubercles of the tooth 37 (the left half of the lower jaw, 7 - the second molar ) and tooth 47 (the right half of the lower jaw, 7 is the second molar) is made at a distance of 27 mm along the transverse axis and at an angle of 69.6 ° to the sagittal axis at a distance of 33.4 mm from the contact point to align with the central incisors of 31 teeth ( left half of the lower jaw, 1 - first incisor) and 41 teeth (right half of the lower h jaws, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, marking each vertex of the distal buccal and lingual tubercles of tooth 37 (left half of the lower jaw, 7 - second molar) and tooth 47 (right half of the lower jaw, 7 - second molar ) was performed at a distance of 28.8 mm along the transverse axis and at an angle of 69.4 ° to the sagittal axis at a distance of 38.6 mm from the contact point for alignment with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 tooth (the right half of the lower jaw, 1 - the first incisor) of the lower jaw on the plaster m put along this axis, the marking of each vertex of the tubercle of tooth 13 (the right half of the upper jaw, 3 is the canine) and tooth 23 (the left half of the upper jaw, 3 is the canine) is made at a distance of 17.6 mm along the transverse axis and at an angle of 90 ° to the sagittal axis at a distance of 9.5 mm from the contact point to align with the central incisors 11 teeth (the right half of the upper jaw 1 is the first incisor) and 21 teeth (the left half of the upper jaw, 1 is the first incisor) of the upper jaw on the gypsum model along this axis , the marking of each vertex of the buccal and palatine tubercles of the tooth 14 (the right half henna of the jaw, 4 - the first premolar) and tooth 24 (the left half of the upper jaw, 4 - the first premolar) is made at a distance of 21.4 mm along the transverse axis and at an angle of 76.6 ° to the sagittal axis at a distance of 16.5 mm from the contact points for alignment with the central incisors of the 11 tooth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw along this axis, marking each vertex of the buccal and palatine tubercles of the tooth 15 (right half of the upper jaw, 5 - the second premolar) and tooth 25 (the left half of the upper person justi, 5 - the second premolar) is made at a distance of 24 mm along the transverse axis and at an angle of 71.3 to the sagittal axis at a distance of 22.6 mm from the contact point for alignment with the central incisors of 11 teeth (right half of the upper jaw, 1 - first incisor ) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking of each vertex of the medial buccal and palatine tubercles of tooth 16 (right half of the upper jaw, 6 - the first molar) and tooth 26 (left half of the upper jaw, 6 - the first molar) performed at a distance 25.6 mm along the transversal axis and at an angle of 56.2 ° to the sagittal axis at a distance of 27.5 mm from the contact point for alignment with the central incisors of 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking each vertex of the distal buccal and palatine tubercles of tooth 16 (right half of the upper jaw, 6 - the first molar) and tooth 26 (left half of the upper jaw, 6 - first molar) is made at a distance of 27.7 mm along the transverse axis and at an angle of 68.9 ° to s the agitital axis at a distance of 33.4 mm from the contact point to align with the central incisors 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on a plaster model according to this axis, the marking of each vertex of the medial buccal and palatine tubercles of tooth 17 (the right half of the upper jaw, 7 is the second molar) and tooth 27 (the left half of the upper jaw, 7 is the second molar) is made at a distance of 29.5 mm along the transverse axis and at an angle 66.6 ° to the sagittal axis and a distance of 38.6 mm from the contact points for alignment with the central incisors of 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking each vertex of the distal buccal and palatine tubercles tooth 17 (the right half of the upper jaw, 7 is the second molar) and tooth 27 (the left half of the upper jaw, 7 is the second molar) is made at a distance of 30.2 mm along the transverse axis and at an angle of 68 ° to the sagittal axis at a distance of 43 mm from contact point for alignment with central incisors 11 s ba (right half of the upper jaw, 1 - first cutter) and 21zuba (left half of the upper jaw, 1 - first cutting edge) of the upper jaw model gypsum along this axis. The proposed dentoalveolar biometric pattern determines the location of the tubercles of the buccal teeth of the upper and lower jaw along the transverse axis, as well as the location of the palatine, lingual tubercles of the teeth in the corners relative to the sagittal axis. By the location of the vertices of the tubercles of the teeth, the correct anatomical shape of each tooth is recreated.

The proposed dentition biometric pattern is illustrated by photographs and drawings where:

figure 1 shows a copy of the model of the lower jaw;

figure 2 shows a copy of the model of the upper jaw;

figure 3 shows a plate with a marking on the outer surface of the lower jaw;

figure 4 shows a plate with a marking on the opposite surface of the upper jaw;

The dento-maxillary biometric pattern consists of a flat plate 1 of a parabolic shape made of transparent organic glass, on which the Cartesian coordinate system with transversal 2 and sagittal 3 coordinate axes is marked.

The marking on the pattern of the surface of the lower jaw 4 of Fig. 3 is made with a contact point 5 for aligning with the central incisors 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw of the gypsum model along the sagittal axis 3, 6 of the top of the tubercles of the tooth 33 (left half of the lower jaw, 3 is the canine) and tooth 43 (of the right half of the lower jaw, 3 is the canine), 7 of the top of the buccal tubercles of the tooth 34 (left half of the lower jaw, 4 - the first premolar) and tooth 44 (the right half of the lower jaw, 4 - the first premolar), 8 in rhinitis of the buccal tubercles of the tooth 35 (left half of the lower jaw, 5 - the second premolar) and tooth 45 (the right half of the lower jaw, 5 - the second premolar), 9 vertices of the medial buccal tubercles of the tooth 36 (left half of the lower jaw, 6 - the first molar) and tooth 46 (the right half of the lower jaw 6 - the first molar), 10 vertices of the distal buccal tubercles of the tooth 36 (the left half of the lower jaw, 6 - the first molar) and tooth 46 (the right half of the lower jaw, 6 - the first molar), 11 vertices of the medial buccal tubercles of tooth 37 (left half of the lower jaw, 7 - second molar) and tooth 47 (right half of the lower jaw, 7 - the second molar), 12 vertices of the distal buccal tubercles of the tooth 37 (the left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar), 13 vertices of the lingual tubercles of the tooth 34 (left half of the lower jaw, 4 - the first premolar) and tooth 44 (the right half of the lower jaw, 4 - the first premolar), 14 vertices of the lingual tubercles of the tooth 35 (the left half of the lower jaw, 5 - the second premolar) and tooth 45 (the right half of the lower jaw, 5 - second premolar), 15 vertices of the medial lingual tubercles of the tooth 36 (left half of the lower jaw, 6 - first th molar) and tooth 46 (right half of the lower jaw, 6 - the first molar), 16 vertices of the distal lingual tubercles of tooth 36 (left half of the lower jaw, 6 - the first molar) and tooth 46 (right half of the lower jaw, 6 - the first molar) , 17 vertices of the medial lingual tubercles of the tooth 37 (the left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar), 18 vertices of the distal lingual tubercles of the tooth 37 (left half of the lower jaw, 7 - the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar).

The marking on the pattern of the surface of the upper jaw 19 of Fig. 4 is made with a contact point 20 for aligning with the central incisors 11 teeth (the right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw gypsum model along the sagittal axis 3, 21 vertices of the tubercles of tooth 13 (right half of the upper jaw, 3 canine) and tooth 23 (left half of the upper jaw, 3 canine), 22 vertices of the buccal tubercles of tooth 14 (right half of the upper jaw, 4 - the first premolar) and tooth 24 (the left half of the upper jaw, 4 - the first pre olar), 23 vertices of the buccal tubercles of tooth 15 (the right half of the upper jaw, 5 - the second premolar) and tooth 25 (the left half of the upper jaw, 5 - the second premolar), 24 vertices of the medial buccal tubercles of the tooth 16 (right half of the upper jaw, 6 - the first molar) and tooth 26 (left half of the upper jaw, 6 - the first molar), 25 tops of the distal buccal tubercles of tooth 16 (right half of the upper jaw, 6 - first molar) and tooth 26 (left half of the upper jaw, 6 - first molar) , 26 tops of the medial buccal tubercles of tooth 17 (right half of the upper jaw, 7 - second molar) and tooth 27 (left half of the upper jaw, 7 - second molar), 27 vertices of the distal buccal tubercles of tooth 17 (right half of the upper jaw, 7 - second molar) and tooth 27 (left half of the upper jaw, 7 - second molar), 28 vertices of the palatine tubercles tooth 14 (the right half of the upper jaw, 4 - the first premolar) and tooth 24 (the left half of the upper jaw, 4 - the first premolar), 29 vertices of the palatine hillocks of the tooth 15 (the right half of the upper jaw, 5 - the second premolar) and tooth 25 (the left half of the upper jaw, 5 - the second premolar), 30 tops of the medial palatine tubercles of the tooth 16 (right half and in the upper jaw, 6 - the first molar) and tooth 26 (the left half of the upper jaw, 6 - the first molar) 31 tops of the distal palatine tubercles of the tooth 16 (the right half of the upper jaw, 6-first molar) and tooth 26 (the left half of the upper jaw 6 - the first molar), 32 vertices of the medial palatine tubercles of tooth 17 (the right half of the upper jaw, 7 - the second molar) and tooth 27 (the left half of the upper jaw, 7 - the second molar), 33 vertices of the distal palatine tubercles of the tooth 17 (right half of the upper jaw 7 - the second molar), and tooth 27 (the left half of the upper jaw, 7 - the second molar).

The device operates as follows.

The piece is placed on the gypsum model of the lower jaw so that the contact point 5 is aligned for alignment with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum models along this axis with the end point of the central incisors 31 and 41, and the sagittal coordinate axis 3 coincided with the sagittal axis of the gypsum model of figure 1. Visually assess the structure of the dentition, teeth and their deviation from the norm. Check the ratio of the sizes of the sagittal 3 and transversal 2 coordinate axes on the gypsum model and on the patterns and determine the increase or decrease of the dental arches, teeth, tubercles of the teeth in these directions. Measurements are made during biometric research in a spatial coordinate system and volume modeling of dental arches, teeth, their tubercles to the norm and the exact ratio with the temporomandibular joint and masticatory muscles. At point 6, the position of the vertices of the tubercles of the 33 tooth (the left half of the lower jaw. 3 is the canine) and 43 teeth (the right half of the lower jaw, 3 is the canine) is determined by the points 7 and 13; the vertices of the buccal and lingual tubercles of the 34 tooth (the left half of the lower jaw) are determined , 4 - the first molar) and 44 teeth (the right half of the lower jaw. 4 - the first molar), at points 8 and 14 determine the vertices of the buccal and lingual tubercles of the teeth of the 35 tooth (left half of the lower jaw. 5 - the second premolar) and 45 teeth ( the right half of the lower jaw, 5 - the second premolar), at points 9 and 15 determine the tops of the medial buccal and lingual tubercles of 36 teeth (left half of the lower jaw, 6 - the first molar) and 46 teeth (right half of the lower jaw, 6 - the first molar) points 10 and 16 determine the vertices of the distal buccal and lingual tubercles of 36 tooth (left half of the lower jaw, 6 - the first molar) and 46 teeth (the right half of the lower jaw, 6 - the first molar), at points 11 and 17 determine the vertices of the medial buccal and lingual tubercles of the 37 tooth (left half of the lower jaw, 7 - the second molar) and 47 teeth (right half of the lower jaw, 7 - second molar), at points 12 and 18 determine the tops of the distal buccal and lingual x cusps of tooth 37 (the left half of the lower jaw, 7 - second molar) and tooth 47 (the right half of lower jaw, 7 - second molar). The piece is placed on the gypsum model of the upper jaw so that the contact point 19 is aligned with the contact point of the central incisors of the 11 tooth (right half of the upper jaw, 1 is the first incisor) and 21 teeth (left half of the upper jaw, 1 is the first incisor) of the upper jaw on the gypsum models along this axis, and the sagittal coordinate axis 3 coincided with the sagittal axis of the gypsum model. Visually assess the structure of the dentition, teeth and their deviation from the norm. The ratio of the sizes of the sagittal and transversal coordinate axes on the gypsum model and on the pattern determines the increase or decrease in the dental arches, teeth, and tubercles of the teeth in these directions. Measurements are made during biometric research in a spatial coordinate system and volume modeling of dental arches, teeth, their tubercles, to the norm and the exact ratio with the temporomandibular joint and masticatory muscles. At point 21, the position of the apex of each tubercle of the 13 tooth (right half of the upper jaw, 3 is the canine) and 23 teeth (the left half of the upper jaw, 3 is the canine) is determined, at points 22 and 28, the vertices of the buccal and palatine tubercles of tooth 14 (the right half) are determined the upper jaw, 4 - the first premolar) and 24 teeth (the left half of the upper jaw, 4 - the first premolar) at points 23 and 29 determine the vertices of the cheek and palatine tubercles of the 15 tooth (right half of the upper jaw, 5 - the second premolar) and 25 teeth ( the left half of the upper jaw, 5 - the second premolar), the points of the media are determined by points 24 and 30 of the buccal and palatine tubercles of the 16 tooth (the right half of the upper jaw, 6 is the first molar) and 26 of the tooth (the left half of the upper jaw, 6 is the first molar), the points of the distal buccal and palatine tubercles of the 16 tooth (right half) are determined by points 25 and 32 the upper jaw, 6 - the first molar) and 26 teeth (the left half of the upper jaw, 6 - the first molar) at points 26 and 32 determine the vertices of the medial buccal and palatine tubercles of the 17th tooth, the right half of the upper jaw, 7 - the second molar) and 27 teeth ( the left half of the upper jaw, 7 - the second molar) at the points 27 and 33 determine the top of the dist nyh buccal and palatal cusps of the tooth 17 (right half maxilla, 7 second molar) and tooth 27 (the left half of the upper jaw, 7 - second molar).

The technical result of the claimed biometric patterns is that it allows to simplify the exact reconstruction of dental arches, teeth, their anatomical shape and the location of the tubercles of the teeth in relation to the temporomandibular joint and chewing muscles, which is important for the function of movement of the lower jaw.

The inventive pattern is used in the educational process when performing educational research and practical work in studying the structure and position of the teeth, their relationship to each other. The proposed pattern helps to master the scientific and practical basis of the anatomy of the dentition and improve the quality of dental care.

Claims (1)

1. A dentofacial biometric piece containing a parabolic plate made of transparent organic glass marked with a Cartesian system with transversal and sagittal coordinate axes, characterized in that the marking of the lower jaw is made on the outer surface of the flat plate, and the marking of the upper jaw is on the opposite surface of the plate, marking each vertex of the tubercles of the tooth 33 (the left half of the lower jaw, 3 is the canine) and tooth 43 (the right half of the lower jaw, 3 is the canine) is made at a distance of 14 mm along the transver zonal coordinate axis and at an angle of 90 ° to the sagittal axis at a distance of 5.2 mm from the contact point to align with the central incisors 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, the marking of each vertex of the buccal and lingual tubercles of the tooth 34 (the left half of the lower jaw, 4 is the first premolar) and tooth 44 (the right half of the lower jaw, 4 is the first premolar) is made at a distance of 17, 6 mm along the transversal axis and at an angle of 48.1 ° to the sagittal axis at a distance of 9.5 mm from the contact point to align with the central incisors 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis , the marking of each vertex of the buccal and lingual tubercles of tooth 35 (the left half of the lower jaw, 5 is the second premolar) and tooth 45 (the right half of the lower jaw, 5 is the second premolar) is made at a distance of 20.5 mm along the transverse axis and at an angle of 73, 4 ° to the sagittal axis at a distance of 16.5 mm from the contact point for alignment with central incisors 31 teeth (left half of the lower jaw, 1 - first incisor) and 41 teeth (right half of the lower jaw, 1 - first incisor) of the lower jaw on the gypsum model along this axis, marking each vertex of the medial buccal and lingual tubercles of the tooth 36 (the left half of the lower jaw, 6 is the first molar) and tooth 46 (the right half of the lower jaw, 6 is the first molar) is made at a distance of 23.2 mm along the transverse axis and at an angle of 69.8 ° to the sagittal axis at a distance of 22.6 mm from the contact point for alignment with the central incisors of the 31 tooth (left half the lower jaw, 1 - the first incisor) and tooth 41 (the right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, marking each vertex of the distal buccal and lingual tubercles of the tooth 36 (left half of the lower jaw, 6 - the first molar) and tooth 46 (the right half of the lower jaw, 6 - the first molar) is made at a distance of 25 mm along the transversal axis and at an angle of 59 ° to the sagittal axis at a distance of 27.5 mm from the contact point to align with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half and the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, the marking of each vertex of the medial buccal and lingual tubercles of the tooth 37 (the left half of the lower jaw, 7 is the second molar) and tooth 47 (the right half of the lower jaw, 7 - the second molar) is made at a distance of 27 mm along the transversal axis and at an angle of 69.6 ° to the sagittal axis at a distance of 33.4 mm from the contact point for alignment with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 tooth (right half of the lower jaw, 1 - the first incisor) of the lower jaw on of the Ips model on this axis, the marking of each vertex of the distal buccal and lingual tubercles of tooth 37 (the left half of the lower jaw, 7 is the second molar) and tooth 47 (the right half of the lower jaw, 7 is the second molar) is made at a distance of 28.8 mm along the transverse axis and at an angle of 69.4 ° to the sagittal axis at a distance of 38.6 mm from the contact point for alignment with the central incisors of 31 teeth (left half of the lower jaw, 1 - the first incisor) and 41 teeth (right half of the lower jaw, 1 - the first incisor) of the lower jaw on the gypsum model along this axis, the marking of each vertex the tubercle of tooth 13 (the right half of the upper jaw, 3 is the canine) and tooth 23 (the left half of the upper jaw, 3 is the canine) is made at a distance of 17.6 mm along the transverse axis and at an angle of 90 ° to the sagittal axis at a distance of 9.5 mm from the contact point to align with the central incisors 11 teeth (the right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking each vertex of the buccal and palatine tubercles of tooth 14 (right half of the upper jaw, 4 - the first premolar) and tooth 24 (the left half of the upper jaw, 4 - the first premolar) is made at a distance of 21.4 mm along the transverse axis and at an angle of 76.6 ° to the sagittal axis at a distance of 16.5 mm from the contact point to align with the central incisors of 11 teeth (right half the upper jaw, 1 - the first incisor) and 21 teeth (the left half of the upper jaw, 1 - the first incisor) of the upper jaw along this axis, marking each vertex of the buccal and palatine tubercles of the tooth 15 (the right half of the upper jaw, 5 - the second premolar) and the tooth 25 (the left half of the upper jaw, 5 - the second premolar) performed on races standing 24 mm along the transversal axis and at an angle of 71.3 ° to the sagittal axis at a distance of 22.6 mm from the contact point for alignment with the central incisors of 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking each vertex of the medial buccal and palatine tubercles of tooth 16 (right half of the upper jaw, 6 - first molar) and tooth 26 (left half of the upper jaw, 6 - first molar ) made at a distance of 25.6 mm along the transverse axis and at an angle 56.2 ° to the sagittal axis at a distance of 27.5 mm from the contact point to align with the central incisors 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, the marking of each vertex of the distal buccal and palatine tubercles of tooth 16 (the right half of the upper jaw, 6 is the first molar) and tooth 26 (the left half of the upper jaw, 6 is the first molar) is made at a distance of 27.7 mm along transversal axis and at an angle of 68.9 ° to the sagittal axis at a distance of 33.4 mm from contact point for alignment with the central incisors of 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking each vertex of the medial buccal and palatine tubercles of tooth 17 (right half of the upper jaw, 7 - second molar) and tooth 27 (left half of the upper jaw, 7 - second molar) made at a distance of 29.5 mm along the transversal axis and at an angle of 66.6 ° to the sagittal axis and the distance 38.6 mm from the contact point for alignment with center points There are 11 teeth (right half of the upper jaw, 1 - the first incisor) and 21 teeth (left half of the upper jaw, 1 - the first incisor) of the upper jaw on the gypsum model along this axis, marking each vertex of the distal buccal and palatine tubercles of tooth 17 (right half the upper jaw, 7 - the second molar) and tooth 27 (the left half of the upper jaw, 7 - the second molar) is made at a distance of 30.2 mm along the transverse axis and at an angle of 68 ° to the sagittal axis at a distance of 43 mm from the contact point to align with central incisors of 11 teeth (right half of the upper jaw, 1 - he first cutter) and tooth 21 (the left half of the upper jaw, 1 - first cutting edge) of the upper jaw model gypsum along this axis.

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