BR102015029037A2 - physical three-dimensional models of teeth and method for their construction - Google Patents

Abstract

physical three-dimensional models of teeth and method for their construction. The present invention relates to a method for constructing three-dimensional physical models of human teeth using images generated from computed microtomography and rapid prototyping equipment.

Description

(54) Title: PHYSICAL THREE-DIMENSIONAL MODELS OF TEETH AND METHOD FOR CONSTRUCTION OF THE SAME (51) Int. Cl .: A61C 13/00 (73) Holder (s): NATIONAL INSTITUTE OF TECHNOLOGY, SOCIETY OF SUPERIOR EDUCATION ESTÁCIO DE SÁ LTDA.

(72) Inventor (s): MÁRCIA TERESA SOARES LUTTERBACH; FLÁVIO RODRIGUES FERREIRA ALVES; JOSÉ FREITAS SIQUEIRA JUNIOR; JOSÉ CLÁUDIO PROVENZANO; THAÍS MEDEIROS DA SILVA (57) Abstract: Three-dimensional physical models of teeth and method for their construction. The present invention relates to a method for the construction of three-dimensional physical models of human teeth, using images generated from computerized microtomography and rapid prototyping equipment.

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Descriptive report for three-dimensional physical models of teeth and method for their construction

Field of the invention [0001] The present invention is comprised in the fields of 3D mold construction and for use in dentistry. More specifically, the present invention relates to physical three-dimensional models of teeth and a method for the construction of physical three-dimensional models of extracted human teeth, using images generated from computerized microtomography (IJTC).

Description of the invention [0002] The present invention relates to a method for the construction of three-dimensional physical models of extracted human teeth, using images generated from computerized microtomography (IJTC), in addition to the possible insertion of additional virtual elements, modeled in specific software. After manipulation, the images are sent to rapid prototyping equipment, aiming to reproduce human teeth in synthetic or biological materials with dimensional fidelity, with the purpose of using them for the simulation of dental procedures protocols, and the development of scientific research in the area. Dentistry, Microbiology and Metallurgy. Background to the invention [0003] In dentistry, orthodontics, prosthetics and dentistry, the use of models is fundamental. The possibility of digitizing plaster models, or even scanning the teeth directly from the patient's mouth, has always been a search for Dentistry, both to avoid discomfort and to speed up work, improve communication between colleagues and with

2/8 prosthesis laboratories, and reduce the physical spaces necessary for the storage of these models.

[0004] The acquisition of a copy of a tooth or several teeth, of adjacent healthy teeth and antagonists, and the establishment of a correct relationship, as well as the conversion of this information into accurate replications of the dentition, are the main objectives of the molding process in Restorative Dentistry.

[0005] The techniques currently used to obtain moldings with elastomers and create plaster models from them have been in use since 1937 (Dent Dig. 1937; 43: 230-4). The first elastomeric material specifically produced for use in dentistry was Impregum, from 1965, a polyether type material, from the company ESPE.

[0006] Digital impression and scanning systems in Dentistry were introduced in the mid-1980s, and have evolved so much that articles already predicted that by 2015, most dentists in the US and Europe would be using digital scanners for impression (Inside Dentistry 2009: 5 (4)). In orthodontics, digital impressions have been used successfully for several years, in systems such as Cadent IOC / OrthoCAD, Dentsply / GAC OrthoPlex, Stratos / Orametrix SureSmile, and EMS RapidForm. The CAD / CAM systems (Computer Aided Design and Computer Aided Manufacture), currently available, are able to feed data obtained through precise digital scans made from plaster models directly to confection systems capable of sculpting restorations in ceramic or resin blocks, without the need for a physical copy of the prepared teeth, adjacent teeth and antagonistic teeth.

[0007] Patent application BR0809900-6, owned by the National Institute of Technology (INT), describes a method for building three-dimensional physical models, however the proposed model is that of fetuses. O

3/8 patent application BR0809900-6 uses files of medical exams of Magnetic Resonance and Computed Tomography, which are prototyped in Rapid Prototyping technology, aiming to reproduce fetuses for medical and / or personal evaluation with dimensional fidelity. The process is carried out by obtaining files in DICOM format, in sequential image cuts, preferably on the sagittal axis. The areas to be built must be selected and may be internal organs and / or external surfaces. In the case of Magnetic Resonance, the individual contour of the areas of interest is necessary. In computed tomography, the virtual model is conceived from a differentiation by image contrast (Threshoulding) indicated by the opacity of the tissue as to the passage of X-rays.

[0008] Patent application WO / 2013/120478 describes the use of a calibrated Hounsfield volume tomography scanner to generate a 3D data set of an anatomical structure of the mouth and / or mandible and a subsequent selection of the desired data to produce prosthesis, model or structure design.

[0009] EP0966927 describes a method and device for producing medical articles, in particular dental prostheses. The device has a camera, an X-ray, ultrasound and a computerized tomography scanner to measure the dimensions of the parts to be replaced.

[00010] The three-dimensional models, in addition to being used in research projects or equipment prototypes, can also be useful to improve teaching, with regard to didactic aspects, as they allow to accurately reproduce dental anatomy, especially the internal one, allowing that undergraduate, graduate students and dentistry professionals train different treatment protocols, under equal conditions of competitiveness.

There is a product on the market, called TrueTooth, that makes 3D molds, however this technology only allows printing on synthetic material and does not allow the insertion of virtual elements generated by software, such as simulation of calcifications, perforations, external resorption, internal resorption , apical resorption, deviations in the path of the root canals and fractured endodontic instruments.

Brief Description of the Drawings [00011] Figure 01 presents the graphic representation of the tooth before the insertion of virtual elements and before the correction of the computer modeling.

[00012] Figure 02 shows the graphic representation of the tooth after the correction of the computer modeling.

Detailed description of the invention [00013] The present invention relates to a method for the construction of three-dimensional physical models of extracted human teeth, using images of real teeth generated from microtomographic scanning, in addition to the possible insertion of additional virtual elements, modeled in specific software, which, after two-dimensional or three-dimensional reconstruction with computer programs, are sent to rapid prototyping equipment (Stereolithography, FOM, Zcorp, Objet, Formiga PI 10, EnvisionTEC 3D, Bioplotter® or FAB @ Home and other brands associated with this technology), aiming to reproduce, with morphological and geometric fidelity, human teeth in synthetic or biological materials, for didactic training and scientific research.

[00014] Computed microtomography (I-1TC) is the high resolution volumetric radiographic technique, used only for inanimate or ex vivo samples. X radiation is produced artificially by accelerating electrons against a high-number metallic material

Atomic 5/8. The result is electromagnetic radiation characterized by high frequency, short wavelength and high penetrating power. [00015] Computerized microtomography (I-LTC) systems have been commercially available for more than two decades. Similar, in principle, to medical computed tomography, the ILTC works by capturing data acquired from different viewing angles, using X-ray attenuation, to reconstruct the image of the sample to be reconstructed in two or three dimensions. analyzed (J. Bone Miner. Res., Washington, (7) 1468-1486, 2010). The resolution of the I-LTC is given in microns. Samples typically range from a few millimeters to a few centimeters in size. The I-LTC can be classified according to the X-ray source into two types: Synchrotron radiation and laboratory I-LTC with Micro / Nano X-ray focus. Synchrotron radiation is generated from an electron storage ring and can be monochromatic, having a specific wavelength. Therefore, different elements can be distinguished according to their atomic number (J R Soe Interfaee (7) 4959, 2010).

[00016] The rapid prototyping (PR) technique emerged in the late 1980s, making it possible for a virtual three-dimensional design conceived on a computer to be built on a physical medium quickly. It is a technology to build three-dimensional models and prototypes using files generated in three-dimensional modeling software (CAO - computer-aided design and CAM - computer-aided manufacturing), or obtained through three-dimensional laser scanners and contact digitizers, or still from files obtained in I-LTC equipment. [00017] The process is carried out by transferring the virtual three-dimensional file generated on surfaces and solids, to the rapid prototyping (PR) equipment, in which the system will start to build the

6/8 models by superimposing millimeter layers of varied raw materials, according to the selected technology.

[00018] With regard to the present invention, the dental models obtained are intended for application in teaching and scientific research and diagnosis for treatments. In teaching, models can be used to improve didactic aspects, as they will accurately reproduce dental anatomy, especially internal anatomy, allowing undergraduate, graduate and dental professionals to train different treatment protocols, under equal competitive conditions. .

[00019] Dental models produced with different levels of difficulty, related to anatomical aspects, such as number of root canals, their curvatures and the possible insertion of virtual elements generated by software (simulation of calcifications, perforations, external resorption, internal resorption, apical resorption , deviations in the path of the root canals and fractured endodontic instruments) can optimize the teaching and research process and the prosthesis diagnosis and production process. As for the application in scientific research, dental models can be used to evaluate the mechanical behavior of sharp dental instruments, such as those used in the mechanical preparation of root canals, collaborating in the standardization of mechanical tests, bringing them closer to the clinical reality.

[00020] When printed on biological materials, they can also be used for scientific research in the area of Microbiology (microbial biofilms).

[00021] In addition to the aforementioned purposes, the obvious contribution of this invention to the ethical issue in Dentistry, referring to the use of human teeth for pre-clinical training and scientific research, stands out.

7/8 [00022] The models are printed from the 14 types of human teeth listed below. It should be noted that the characterization below refers only to the length and number of roots, since the internal anatomy and volume are extremely variable and can be complemented with the virtual elements generated by software: Upper central incisor with length between 19 mm and 24 mm, with a root; Upper lateral incisor between 18 mm and 25 mm in length, with a root; Upper canine with length between 18 mm and 30 mm, with a root; First upper premolar between 18 mm and 24 mm in length, with one or two roots; Second upper premolar with length between 18 mm and 24 mm, with one or two roots, fused or differentiated; First molar with length between 17 mm and 24 mm, with 3 roots, fused or differentiated; Second molar with length between 17 mm and 25 mm, with 3 fused or differentiated roots; Lower central incisor between 15 mm and 23 mm in length, with a root; Lower lateral incisor between 15 mm and 24 mm in length, with a root; Lower canine with length between 16 mm and 28 mm, with one or two roots; First lower premolar between 17 mm and 24 mm in length, with one or two roots; Second lower premolar between 17 mm and 25 mm in length, with one or two roots; Lower first molar between 17 mm and 24 mm in length, with one, two or three fused or differentiated roots; Second molar with length between 17 mm and 25 mm, with one, two or three fused or differentiated roots. After performing the computerized microtomography and obtaining the 3D files, they are exported to software that smoothes the surface, since the composition of the enamel and dentin takes the reflective surface. Optionally, the image can be complemented with additional virtual elements, such as simulation of calcifications,

8/8 perforations, external resorption, internal resorption, apical resorption, deviations in the path of the root canals and fractured endodontic instruments).

[00023] The resulting virtual three-dimensional model is transformed into an STL or other extension to be sent to rapid prototyping equipment (Stereolithography, FOM, Zcorp, Objet, Formiga Pl 1 0, EnvisionTEC 3D Bíoplotter® or FAB @ Home and other associated brands with this technology), where the construction of the physical model will be done.

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Claims (4)

Claims 1. Method for building three-dimensional physical models of human teeth characterized by containing the steps of: i. Imaging of teeth by computerized microtomography; ü. Sending the image obtained in step i to specific software for each prototyping equipment; iii. Surface smoothing containing enamel and dentin; iv. Insertion of additional virtual elements modeled in software, optionally; v. Transformation of the resulting three-dimensional model into an STL extension; saw. Two-dimensional or three-dimensional reconstruction with computer programs; vii. Shipment of the reconstruction of step vi for rapid prototyping equipment; viii. Construction of physical models by superimposing millimeter layers of various raw materials. 2. Method for building three-dimensional physical models of human teeth according to claim 1 characterized by the software being specific to each prototyping equipment used in step ii. 3. Method for building three-dimensional physical models of human teeth according to claim 1, characterized by the fact that the virtual elements are understood, but not limited, in the group consisting of simulation of calcifications, perforations, external resorption, internal resorption, resorption apical, 2/2 deviations in the path of the root canals and fractured endodontic instruments. 4. Method for building three-dimensional physical models of human teeth according to claim 1 characterized by the fact that rapid prototyping equipment is included, but not limited, in the group consisting of Stereolithography, FOM, Zcorp, Objet, Formiga Pll 0 , EnvisionTEC 3D Bioplotter® or FAB @ Home. 1/2 ί · STLViewêr ~ ^^^ ~ File View Window I β 9 ”« t © e V ess fl · ¹ Denlifu2S4 re <feí-stl Modeme Infemeion β x] Omenaons Mn Max Mto X -160,000 115-000 275,000 rnn Y -es.000 126.000 211.000 mm Z 138,500 413-SOO 275,000 im BR * □)