GR20200100184A - Method for the chromometric determination of the optimal recovery material in dentistry - Google Patents

Abstract

The invention relates to a chromometry method for use in dental science and clinical practice. It consists of a special gray photo equalization card and a database software. The use of the card, in combination with a special image-processing software 5, aims at the accurate measurement of the color dimensions of objects (Lab) and the transparency thereof (Translucency Parameter TP). The card has areas of known visual properties (CIELab 1976 System) and areas of white and black color in neighboring display. It also has focusing aids. Said method involves the measuring of teeth transparency which is defined by the difference between the Lab in front of white color and the Lab in front of a black background and results from a known mathematical relation that defines the color values ??in front of a white background (LB, aB and bB are values in front of the black background).

Description

DESCRIPTION

Method of colorimetric determination of optimal restorative material in dentistry.

The present invention relates to a colorimetric method for use in dentistry. The method is not only limited to the measurement of the color coordinates of the teeth, but also includes the measurement of their transparency, a parameter that the existing methods (spectrophotometers, e-lab) ignore, despite the fact that transparency is the most basic visual element of dental tissues and its performance determines the aesthetic failure or success of their restoration. A specially designed photographic gray balance card and software is used to objectively measure the optical dimensions of the teeth and transparency.

Despite the fact that color has measurable dimensions, to this day the dental community uses visual observation as the primary method of color selection. The main point of reference is the "Vita" color chart, which was manufactured in 1927 and did not refer to human teeth, but to the company's "Helios" commercial line of teeth for dentures.

Although the color dimensions of the "Vita" color chart are fixed, the composite filling resin companies do not reproduce them exactly, despite the fact that they are usually referred to by name. Likewise, companies that have independent color series without reference to the "VITA" color chart, manufacture their color range without any standardization.

The "Vita" color chart, as well as any of the material series not listed in it, does not give information on the exact transparency of the materials. Their description is mainly qualitative (more or less transparent colors), although transparency is a measurable quantity, it can be accurately quantified and is referred to as the fourth dimension of color.

The already existing color sampling devices (spectrophotometers) also do not have the ability to measure transparency. So is the photographic method with the brand name "e-lab" which has been introduced in recent years. Therefore, no identification of the materials can be made with the transparency of the teeth, even though this is the most important factor for choosing the right material for their restoration.

Optical photographic equalization cards (grey cards) when simultaneously displayed in the plan of taking a photograph serve as points of known optical dimensions for processing with software (software) and equalizing the photograph or video, Optical photographic equalization cards are used during the last years in dental photography in order to measure the color dimensions of teeth and achieve objective communication with dental laboratories (see figure 1). But none of the existing photo cards take into account the transparency of objects, which especially in dental photography provides the most important elements for reproducing the natural optical properties of natural teeth. In particular, with existing methods, the visual perception of high-transparency areas is depicted by a drop in brightness, and the actual three-dimensional visual properties of objects are depicted as a two-dimensional change in the white-black axis.

In dental practice, the application of the above color sampling methods leads to a large percentage of the incorrect color choice of tooth restoration materials and consequently to blockages that do not exactly correspond to the optical properties of the teeth. The purpose of the present invention is to eliminate the aforementioned disadvantages by offering a method of quantitative selection of the transparency and color of immediate dental restoration materials using software and a digital photograph to be taken by the user via a mobile phone or palmtop device for immediate measurement, analysis and indicating said optimal material according to the measurement of the color dimensions of the tooth. During the above procedure, a photographic equalization optical card (grey card) will be used, modified to enable the measurement of transparency. The use of the card in combination with special image processing software aims to accurately measure both the color (Lab) dimensions of objects and their transparency (Translucency Parameter TP),

The features of the invention are defined in the claims

• Balance Card Features:

The overall dimensions of the card will be 20mm by 30mm, so that intraoral placement is possible. It will have two areas with adjacent white-black imaging, one on one side with dimensions of 20 mm, for the cases where transparency measurement of larger areas is required (such as the entire aesthetic zone) and one in the opposite corner in order to serve the cases where it is required measuring the transparency of individual teeth, according to figure 2. The body of the card will be neutral gray (a=0 and b=0) and of known brightness (L) (Lab dimensions according to the CIELab1976 system). In the gray area it will display a target or logo to help focus when shooting.

· Card placement procedure during photo shoot:

The card will be placed intraorally, behind the incisal edges of the teeth in such a way that the surface of interest for measurements is divided anteriorly by the white and black areas. The focus will be on the corresponding gray area.

· Edit the electronic file of the photo

After the photo is taken it can be used to equalize it in the true color dimensions, image processing software or the special software made as an application for mobile phone devices for this purpose. Equalization is done by processing the image so that the pixels in the gray area of known optical dimensions are displayed at their actual values.

The whole process of equalization, measuring transparency calculation, matching to material can be done on a computer with manual image processing or via a mobile phone device (smart phone) with the special software (app) built for this purpose.

If for the above purpose the special software of mobile devices manufactured is used, the sequence is as follows:

A. the software asks to define the clinical dental case (Class III or W by Black or resin face). If class III is selected, the brightness will be assigned first, while in the other two cases the transparency of the teeth will be selected as a priority for the selection of the appropriate material (image 3). B. the software asks for information on the clinical approach, i.e. if the lesion will be restored with a single material or if dentin-enamel layering will be chosen (figure 4).

C. the software requests information about the thickness of the lesion to be restored (image 5).

D. the software asks for the photo to be taken or uploaded from an existing file (image 6).

E. the software asks to indicate the gray area (select gray pixel) (image 7).

F. the software asks to indicate the measurement area (picture 9).

G. the software asks to indicate the area of the tooth in front of the black area of the card (image 10).

H. the software asks to indicate the area of the tooth in front of the white area of the card (image 11).

I. the software equalizes the image, makes the measurements (L,a,b) of the corresponding areas, calculates the tooth color (L,a,b) and the transparency (Translucency Parameter) based on the formula TP=[(LB -LW)<2>+(aB-aW)<2>+(bB-bW)<2>]<1/2>

where LW, aW and bW are defined as the color values in front of the white background, while LB, aB and bB are the values in front of the black background, and based on the existing database with the optical properties (L, a, b, TP) of the materials (resins) suggests the most appropriate choice. The database consists of experimental measurements of the available materials in various thicknesses which is constantly updated and renewed by the software managers (figure 12).

The procedure that will be followed by the photographic image equalization card

software with its simultaneous use is described in its layout

Claims (13)

1. Method of extracting color conclusions from a photographed object and matching them to colors of composite resin materials consisting of: a. Method of taking a color photograph of the object b. Taking the photo while using a color reference card that will be in contact with the object c. A means of analyzing the color dimensions and transparency of the photographed object. The color dimensions in the image are measured in the displayed pixels after equalizing the image to the true color dimensions using the modern object display of known color dimensions. d. Transmission of the data to a place far from the place where the photo was taken e. Means of converting the color inferences extracted from the photographed object into parameters which can lead to the reproduction of the color dimensions of the object through a color palette. 2. A method according to claim 1 wherein the means of capturing the color photograph is a mobile phone. 3. A method according to claims 1 and 2 characterized in that the means of taking the photograph is a mobile phone having an external light source and the possibility of vertical polarization filters. Devices of this type are already commercially available (example MDP by Smile Lite https://www.styleitaliano.org/smileline/smilelite-mdp/). 4. A method according to claims 1 to 3 characterized in that the color reference card is gray with dimensions (CIELab) L=75, a=0, b=0 5. A method according to one of the preceding claims, characterized in that the color reference card has adjacent white and black areas. 6. A method according to one of the preceding claims, characterized in that the adjacent white and black areas of the color reference card are placed behind the photographed object. 7. A method according to one of the preceding claims characterized in that the color reference card is placed in a position to be displayed in the frame of the photograph to be taken to be used as a reference color. 8. A method according to one of the preceding claims, characterized in that a photograph of the object is taken while simultaneously using the color reference card. 9. A method according to one of the preceding claims, characterized in that the display of the object is equalized by software on the mobile device so that the display of the pixels of the gray area corresponds to the actual color values (CIELab L=75, a=0 , b=0) 10. A method according to one of the preceding claims, characterized in that with a photographic image the color dimensions of the object are recorded first without the use of the color reference card, then the color dimensions of the object in front of the white area (LW , aW, bW) and finally recording the color dimensions of the object in front of the black Area (Lb, aB, bB). 11. A method according to one of the above claims, characterized in that the color conclusions drawn from the photographed object (L,a,b,TP) are transmitted via the Internet for comparison with corresponding color values relating to commercial resin formulations. The database can be constantly updated following measurements of the optical properties of new materials on the market. 12. A method according to one of the above claims characterized in that the database will match the color conclusions drawn from the photographed object to the most suitable commercial formulation or combination of composite resin formulations for optimal reproduction of the color and transparency of the photographed object object. 13. A method according to one of the above claims, characterized in that the user is informed through the color measurements of the dental composite resin. application for the optimal matching of tissues to a material or combination of materials