BR202014015786U2 - positioning intraoral longitudinal standardizer of radiographs - Google Patents

Abstract

longitudinal intraoral positioner of radiographs. The present utility model refers to a longitudinal intraoral positioner of radiographs (pr) (1) that allows subsequent images to be taken with the same geometric position; it allows geometric standardization between the positioner and the x-ray machine. and between the positioner and the radiographic area, allowing to reproduce, in geometric terms, a periapical or interproximal dental radiograph at different times, but with the differential of maintaining a fixed coordinate system over time. It also allows the radiographs generated to be analyzed by radiographic subtraction, fractal analysis, or any other technique that identifies very subtle changes that may occur over time in the oral cavity during the radiographic interval, without can be detected by the human eye.

Description

FIELD OF THE INVENTION [1] The present utility model falls within the field of application of dentistry, more specifically, applied and / or adapted dental diagnostic devices which relates to an intraoral radiographic patterner longitudinal positioner which enables subsequent imaging with the same geometrical position to be made, because the invention provides repeatability and reproducibility in radiographic shots. BACKGROUND OF THE INVENTION There are already a number of positioner options available on the market. such as those produced by Indusbello and Maquira. Both products seek radiographic standardization, but their limitations are to reproduce the periapical and interproximal radiographs, at different times, in the same geometric position between the positioner and the region to be radiographed. These products allow only the standardization of the geometric distances between the positioner and the X-ray machine. The lack of standardization of the geometric position between the positioner and the region to be radiographed does not allow the repeatability and reproducibility of radiographic images, therefore it does not allow their use to perform radiographic techniques that require subsequent standardized images, such as the radiographic subtraction technique, or fractal analysis, which require geometric standardization between both the positioner and x-ray distance and between the position positioner and the region to be radiographed, that is, a coordinate origin always fixed between the different radiographic sockets over time, to always have a reference or comparison basis. [3] Radiographically, for any kind of alteration of the mineral constituent of bone or tooth to be subjectively detected by the human eye, a modification of its constituents in the order of 30 to 50% is required. But this modification order can be very damaging as it triggers a problem no longer incipient. [4] In the radiographic subtraction technique, images from two radiographs taken at different times, but with the same coordinate or reference system, are digitally subtracted, so that the structures present in both are removed and the resulting image presents only the difference between them, that is, only shows the image of the mineral reduction or increase, allowing the objective detection of changes in the order of 1 to 5%. In the fractal analysis technique, which has been used in dentistry to evaluate the complexity of bone trabeculate, for diagnosis of osteopenia and osteoporosis, the use of standardized images would allow the detection of morphological alterations of bone trabecular microarchitecture that are undetectable in radiographic examinations. intra-oral radiographs evaluating non-standardized radiographs performed at different times. [5] The use of these image analysis techniques only contributes favorably to dentistry, as in any area of radiology, as it allows diagnoses of incipient alterations, subjectively undetectable by the human eye. [6] The great difficulty in making use of these image analysis techniques as a common procedure, both in the clinic and in research, is due to the inexistence of a device that allows the periapical radiographs to be prepared simply and comprehensively. and geometrically identical interproximal at different times.

BACKGROUND ART [7] US5473662 relates to a radiographic positioner that generates periapical radiographs that can be analyzed by the radiographic subtraction technique. However, its use is limited, as it allows only standardized images of dental implants during their healing phase, or rehabilitated implants with screwed crowns, since the device must be screwed directly onto the implant installed in the oral cavity. . [8] US509G47 describes a radiographic positioner system for repositioning radiographic films for intraoral diagnosis. It can be applied to accurately reposition the film, however, the object of this document does not take into account another important feature that is the bisector technique and is inefficient due to the need to store the entire bite register assembly and the bite. In the present utility model only records with the proper media should be kept. [9] A rigidly fixed radiographic positioner provided with an individualized film device for each patient is described in patent application MU 8300979-5 comprising a round shaped clamp whose opening and closing are made by two screw and thread adjustable shoes. , in which two radiographic devices are attached to the radiographic cylinder. Attached to the opposite side of the shoes is the radiological positioner (PR), whose metal rod has two perpendicular folds, having at its end two coupling pins, the individualized film device (DFI) for each patient has two holes, which They are coupled to the pins of the PR, which has a body provided with upper and lower tabs, having at its adjacent end a nail-shaped support, where the radiographic film is placed. In its use, the dental surgeon places dental resin on the upper and lower flaps of the DFI and thus promotes the rigid fit of the patient's teeth into it, forming an impression of the teeth, which are stored for future radiography. However, to obtain the registration of the supporting teeth, the method of fixation of the DFI to the PR is deficient, not guaranteeing the positioning and parallelism of the film with the radiographed tooth. The present Utility Model (MU) has a guide for interocclusal registration. in one piece, with sliding fittings in PR, which provide greater stability and accuracy. In addition, the present MU has two PR clamping rings on the X-ray tube. These two aspects enable greater rigidity of the entire PR assembly and thus lead to better accuracy in repeating subsequent imaging.

It is worth mentioning that the present MU also has a millimeter rod for individualizing the distance between it and the area to be radiographed. [10] Patent application PI08053430 relates to a radiographic film positioning device and method for obtaining radiographic images which is provided with three sets for positioning the radiographic film comprising at least one means for associating with a radiographic support. positionable substantially perpendicular to a bone portion of the patient. However, such a device cannot maintain a fixed coordinate system over time to allow radiography to be analyzed using the radiographic subtraction technique. [11] Patent applications MU83018042, and MU 88021866, describe a driver for radiographic imaging of patients with dental arch under absolute isolation from an anatomically developed structure that allows them to be accommodated inside. of the mouth, under the insulation cover of the dental arch (rubber sheet), to position the fixative base of the radiographic film in parallel with the isolated tooth and to support the jaw so that it does not move when taking the image, as well as how to direct the ampoule of radiographic equipment that emits X-ray waves at the exact point, the constructive solution being to use a bite block inferior to the structure and a cutout at the base of the radiographic film to create sufficient physical space. to compensate for the part of the file or cone which extends beyond the crown of the tooth and which provides for a stem from which the same structure can be by manual intervention. However, they do not allow the repetition of subsequent imaging for the radiographic subtraction technique because they do not have a fixed coordinate system over time and therefore do not conflict with the present invention. [12] Patent application MU72011297 relates to a dental interproximal radiographic standardization device comprising two position plates of the common periapical radiographic film in the anterior portion; a triangular elevation capable of standardizing the position of the device in the patient's mouth at the intermediate portion; and by a thin bar angled with respect to the anterior and intermediate portions; and by two semicircles parallel to each other and joined to the bar, and by a smaller bar, perpendicular to the previously described, which standardize the positioning cylinder placement of dental X-ray devices. However, although they have semicircles for coupling to the x-ray machine, they do not allow the repetition of subsequent imaging for the radiographic subtraction technique, since they do not have a fixed coordinate system over time.

OBJECTIVE AND ADVANTAGES OF THE INVENTION [13] The present utility model is innovative in providing repeatability and reproducibility in radiographic shots to solve the above problems. Thus, it will provide significant advantages over intraoral positioners and state-of-the-art radiographic methods, which require longitudinally standardized images, enabling an increase in their performance and presenting a more favorable cost / benefit ratio. [14] The present utility model also has the advantage of comprising a device that enables all cases of periapical or interproximal radiographs to be treated in dentate, partially dentate, or implant-rehabilitated patients when follow-up and / or treatment evaluation and management is required. or other health treatment.

BRIEF DESCRIPTION OF THE INVENTION [15] The present utility model relates to a longitudinal radiographic patterner (PR) intraoral positioner (1) which allows subsequent images with the same geometric position to be taken. [16] The invention comprises a millimeter rod for coupling to the x-ray cylinder at one end and the other end, holder for coupling digital sensor or radiographic film and template with occlusal surface markings of the patient, with practical geometry for adaptation to posterior and anterior teeth.

BRIEF DESCRIPTION OF THE DRAWINGS [17] Figure 1 shows the longitudinal intraoral positioner of radiographs (PR) (1) with groove (2) under different views: perspective (a), frontal (b), lateral (c) and upper (d). [18] Figure 2 shows the PR (1) and the interocclusal registration guide (GRI) (3), the latter with sliding fit and holes (4), under different views: perspective (a), front (b), lateral (c) and upper (d). [19] Figure 3 shows the GRI (3) in one piece, already coupled to PR (1), under different views: perspective (a), front (b), side (c) and top (d). [20] Figure 4 shows the PR (1) coupled to an x-ray tube (5) through a double clamp guide (EGA) fitting (6) at different times once the position of EGA reference (8) of the end of the x-ray tube (5). [21] Figure 5 shows PR (1) coupled to an x-ray tube (5) via EGA (6) and GRI (3) coupled to PR (1). [22] Figure 6 shows an acrylic resin template (9), already marked with the occlusal surface, attached to the GRI (3). [23] Figure 7 shows in cross-section an upper posterior tooth (10) occluding in the acrylic resin template (9), already with the occlusal surface marks, coupled to the GRI (3) and PR (1) in the tube. x-rays (5), highlighting the millimeter rod (11) in PR (1) coupled and fixed to the EGA (6) by means of a screw (12). [24] Figure 8 shows an example of radiographic uptake of the upper dental arch through the x-ray beam (13) and its projection over the sensor (14) positioned in the PR (1). The upper (10) and lower (15) posterior teeth are occluded with the resin template with the upper (9) and lower (16) teeth occlusion markings, which are coupled to the upper (3) and lower (17) ) from GRI. Another embodiment of the double clamps (7) of the EGA (6) is presented by fixing screws (18) thereof to the x-ray tube (5). [25] Figure 9 shows an example of radiographic view of the lower arch (13). [26] Figure 10 shows another example of GRI, but composed of two parts, one upper (19) and one lower (20), coupling to the groove (2) of PR (1). The GRIs (19 and 20) are shown with the holes (4) for coupling and securing the resin templates with the upper and lower teeth occlusion markings (9 and 16). [27] Figure 11 shows examples of PR clamps: Figure 11a shows a sliding rack clamp (21); Figure 11b shows a locking support bracket (22); and Figure 11c shows a bolt-on rack clamp (23). [28] Figure 12 shows another one-piece GRI engaging mode with snap-in / retention groove (2) of PR (1) with "dovetail" rail (24). [29] Figure 13 shows another two-piece (top and bottom) GRI snap-in mode with triangular shoulder engagement / retention (25) for coupling to PR (1), which has triangular recess (26) forming a male socket (GRI) female (PR), illustrated through different views: perspective (a), front (b), side (c) and top (d).

DETAILED DESCRIPTION OF THE INVENTION [30] The longitudinal intraoral radiographic positioner (PR) (1) of the present utility model allows geometric patterning between the positioner and the X-ray apparatus and between the positioner and the x-ray area, allowing to reproduce, in geometric terms, a dental periapical or interproximal radiograph at different times, but with the differential of maintaining a fixed coordinate system over time. In addition, it allows the radiographs generated to be analyzed by radiographic subtraction, fractal analysis, or any other technique that identifies very subtle changes that may occur over time in the oral cavity during the radiographic interval, without can be detected by the human eye. [31] The required positioner is anatomically shaped to the oral cavity, which allows its use on posterior and anterior teeth without discomfort for the patient, as well as its use for conventional and digital perapical radiographic films. [32] In addition, the present utility model provides references (millimeter ruler) that allow the dentist to write down data for future consultation when acquiring a new radiograph. In addition, the acrylic resin template, which enables individualized occlusal registration between patients and between radiographic areas of the same patient, can be removed and repositioned to the radiographic positioner at any time and accurately. This also reduces the cost to the practitioner and / or researcher as they would only have to purchase new templates for each area to be analyzed and not a positioner for each area as used in current research. [33] The intra-oral longitudinal positioner of radiographs (PR) (1) comprises groove (2); interocclusal registration guide (GRI) (3); guide bracket with double clamp (EGA) (6) (7); millimeter rod (11) and screw (12) - [34] Figure 1 shows the radiographic positioner (PR) (1) with groove (2) for positioning the interocclusal registration guide (GRI), under different views: perspective (a ), front (b), side (c) and top (d). [35] Figure 2 shows the PR (1) and GRI (3), the latter with sliding fit and holes (4) for retaining interocclusal recording material under different views: perspective (a), front (b) ), lateral (c) and upper (d). [36] Figure 3 shows the GRI (3) in one piece, already coupled to PR (1), under different views: perspective (a), front (b), side (c) and top (d). [37] Figure 4 shows the PR (1) coupled to an x-ray tube (5) through a double clamp guide (EGA) fitting (6) (7) to facilitate repositioning of the PR into the ray tube. x and give greater accuracy in the repetition of new radiographic shots at different times once the EGA reference position (8) of the end of the x-ray tube has been recorded. [38] Figure 5 shows PR (1) coupled to an x-ray tube (5) via EGA (6) and GRI (3) coupled to PR (D - [39] Figure 6 shows a template in acrylic resin (9), with the marks on the occlusal surface of the patient's teeth to be evaluated, coupled with the GRI (3), thus allowing individualized occlusal registration between patients and between radiographic areas of the same patient. repositioning is facilitated once the measurements on the rod are marked and the positioner is fixed to the x-ray tube with clamps. [44] Figure 11 shows different examples of clamps. Figure 11a shows a sliding rack clamp (21 ); Figure 11b shows a locking support bracket (22); and Figure 11c shows a bolt-on rack bracket (23), under different views, which can be used on the PR EGA. [45] Figure 12 shows GRI plug-in, one-piece, snap-on groove (2) of PR (1) with "dovetail" rail (24). It consists of a trunk-conical "swallowtail" section geometry so that the GRI locks into the positioner at the end of the sliding groove (2) of the PR (1). [46] Figure 13 shows another two-piece (top and bottom) GRI snap-in mode with triangular (25) or cylindrical (not shown) shoulder snap-in / retention for PR engagement (1), which instead groove, has triangular recess (26) forming a male (GRI) female socket (PR), illustrated through different views, perspective (a), front (b), side (c) and top (d). [47] PR (1) can be made of materials such as fibers, ceramics, polymers, among others as well as their combination, with the possibility of adding silver nanoparticles to make the product resistant to contamination by microorganisms. pathogenic and presents shape and dimensions compatible with the oral cavity, infant or adult. [48] PR (1) can be made by methods such as injection, thermoforming, rapid prototyping, lost wax carving, among other possible methods, and their combination. [49] Once the PR type has been defined by the GRI fitting type, it will only be necessary to make a new acrylic resin template for each patient and each x-ray area to be radiographically monitored over time. [50] The enhancements to this utility model are listed in simplified form below: • Provides greater effectiveness for obtaining longitudinally standardized radiographic images for use with radiographic subtraction, fractal analysis, or any technique requiring repeatability and image reproducibility, relative to current models; • Provides better diagnosis and prognosis for various areas of Dentistry, such as Periodontics, Dentistry, Implantology, and Dentistry; • Allows to disseminate and popularize techniques of radiographic subtraction, fractal analysis, and others, efficient, but with great difficulties of technical execution with current resources; • Enables optimal geometric standardization of low cost periapical and interproximal radiographs; • Can be applied to any dental element; • It is easy to assemble and operate; • It has low construction cost, making it accessible to all patients; • Features low operating and maintenance costs. [51] It is further noted that the positioner described in this application is not limited to the applications mentioned herein. Thus, it is obvious to those skilled in the art that changes and modifications may be implemented to improve the design without such changes being covered by the scope of this utility model.

REINDICATIONS

Claims (17)

1. Intra-oral longitudinal positioner of radiographs (PR) (1) / CHARACTERIZED by the fact that it comprises groove (2); interocclusal registration guide (GRI) (3); guide bracket with double clamp (EGA) (6) (7); millimeter rod (11) and screw (12). Positioner according to claim 1, characterized in that the groove (2) is for positioning the interocclusal registration guide (GRI) (3). Positioner according to Claim 1, characterized in that the GRI (3) comprises sliding engagement and holes (4) for retaining the interocclusal recording material. Positioner according to claim 3, characterized in that the interocclusal recording material is individualized between patients and between radiographic areas of the same patient. Positioner according to Claim 3 or 4, characterized in that the GRI (3) comprises other one-piece locking / retaining arrangements in the groove (2) of the PR (1) "tail-type" rail. Swallow "(24) and / or triangular shoulder engaging / retaining (25), for coupling in PR (1) with triangular recess (26), forming a male (GRI) female fitting (PR). Positioner according to claim 1, characterized in that the double clamp guide (EGA) fitting (6) is to facilitate repositioning of the PR (1) in the x-ray tube (5) and checking greater accuracy in the repetition of new radiographic shots at different times once the reference position (8) of the EGA (6) of the end of the x-ray tube has been recorded. Positioner according to claim 6, characterized in that another embodiment of the double clamp guide (EGA) fitting (6) is provided by fixing screws (18) thereof to the x-ray tube ( 5). Positioner according to claim 6 or 7, characterized in that the clamps are preferably a sliding rack clamp (21); support bracket with lock (22); or bolt-on rack clamp (23). Positioner according to claim 1, characterized in that the millimeter rod (11) is coupled to the PR (1) and fixed to the EGA (6) by means of the screw (12). Positioner according to Claim 9, characterized in that the millimeter rod (11) is for standardizing the distance between the x-ray apparatus and the area to be radiographed. Positioner according to claim 1, characterized in that it is preferably made of materials such as fibers, ceramics, polymers or a combination thereof. Positioner according to Claim 11, characterized in that it optionally comprises silver nanoparticles. Positioner according to claim 11 or 12, characterized in that the confection is preferably carried out by methods such as injection, thermoforming, rapid prototyping, lost wax carving or a combination thereof. Positioner according to claim 1, characterized in that it has a shape and dimensions compatible with the oral cavity, child or adult. Positioner according to claim 1, characterized in that it is applied to any dental element. Positioner according to Claim 1, characterized in that it allows the geometric reproduction of a dental periapical or interproximal radiograph at different times with a fixed coordinate system over time. Positioner according to claim 1, characterized in that it is for use with radiographic subtraction, fractal analysis, or other techniques requiring repeatability and reproducibility of images.