Patent ID: 12207899

DETAILED DESCRIPTION

In the following description, reference is made to the accompanying figures, which show by way of illustration how the invention may be practiced.

FIG.1shows a dental chart used for recording tooth condition information. This dental chart100has standardized regions representing the surfaces and the root of each tooth. For example the dental chart100has regions101,102and103representing the lingual, occlusal and buccal surfaces, respectively, of tooth #32 while region104represents the roots of that tooth.

The regions representing the tooth surfaces can be shaped to resemble the teeth even more than seen inFIG.1or be more schematic. Most dental charts has regions for all teeth usually found in the human mouth as also seen in the chart illustrated inFIG.1. Different symbols can be used for visualizing the tooth condition information derived for the patient's teeth. In the dental chart ofFIG.1there is among other things a composite filling in tooth11symbolized by a ring filled with dots105.

Such dental charts have been known for decades in paper form and are also part of many digital dental practice management systems where a digital dental chart is used.

FIG.2shows a schematic of a flowchart210for an embodiment.

In step211the digital 3D representation of the patient's teeth with the shape data describing the topography of the teeth is obtained. The digital 3D representation can be recorded using an intra-oral scanner, such as the TRIOS intra-oral scanner produced by 3 shape A/S or by scanning an impression of the teeth or a physical model if the teeth manufactured from the impression.

The digital 3D representation is loaded into a data processing system having a non-transitory computer readable medium encoded with a computer program product having computer readable instructions for identifying and segmenting the individual teeth from the remaining parts of the digital 3D representation (step212). These operations provide that digital models of the individual teeth are obtained and given the corresponding teeth number.

The tooth identification can be handled by tooth recognition algorithms executed by the data processing system where e.g. the digital models of the individual teeth are compared with standardized teeth CAD models for the different types of teeth normally found in person's mouth. The identification can also be based on symmetry across the patient's medial plane which provides a reference for the teeth numbering.

In step213the diagnostic data for the teeth is obtained. The diagnostic data can e.g. be color data, shade data, fluorescence data, Infrared data, Cone beam computed tomography (CBCT) data, and occlusal contact data.

FIG.2illustrates obtaining of the digital 3D representation211and the diagnostic data213as separate steps. However this is not necessarily the case since some diagnostic data may be obtained as part of the digital 3D representation, i.e. such that actions of steps211and213are performed in one single step. If for example an intra-oral scanner is configured for recording color, such as the TRIOS 3 intra-oral scanner, diagnostic data in the form of color or shade data can be recorded simultaneously with the shape data of the digital 3D representation. The obtained digital 3D representation then comprises both shape data and diagnostic data for the teeth.

The diagnostic data are also loaded into the data processing system and in step214tooth condition information is derived from the obtained diagnostic data. The analysis for deriving the tooth condition information depends on the character of the diagnostic data and the information that is being derived.

In case the diagnostic data are fluorescence data the derived information can relate e.g. to the presence of caries or cariogenic bacteria in a part of the patient's tooth or the presence of fillings or dental restorations. Cariogenic bacteria produce porphyrin compounds which emit a fluorescent signal at wavelengths above 600 nm in response to excitation by a probe light at wavelength of 405 nm. If the porphyrin compounds are present on part of the tooth surface there will be a stronger fluorescent signal from that part of the tooth surface and the cariogenic bacteria are detected from the local increase in the intensity of the fluorescence.

The fluorescence data can be recorded as part of the digital 3D representation using a scanner which detects the shape data based on probe light reflected from the teeth surfaces and simultaneously records the longer wavelength fluorescent signal. This can be realized if the probe light is provided by a blue LED or laser emitting light at a wavelength of 405 nm and the detector of the scanner applies a Bayer filter to distinguish between the reflected light and the fluorescent signal. In that case the fluorescence data can be recorded simultaneously with the reflected light and the recorded digital 3D representation comprises both shape data and the fluorescence data.

The analysis of the diagnostic data can be made by an operator based on a visualization of the diagnostic data e.g. in a user interface for configured for assisting the operator in performing steps of the method. For instance diagnostic data in the form of Infrared data for the patient's teeth can be presented in the user interface and the operator can identify tooth sections scattering the infrared light as e.g. caries or fractures in the enamel of the tooth.

The analysis can also be performed by a computer program product having instructions for detecting variations in e.g. the intensity of the diagnostic data over the tooth. For example the scattering of infrared light by a fracture in the enamel will cause a locally lower intensity of the transmitted infrared light. The presence and position of such a local intensity minimum can be derived by the computer program product whereby the tooth condition information is derived from the analyzed diagnostic data.

In step215the digital dental chart is obtained. This can be obtained from a database of a dental practice management system and either be a clean template for the recording of tooth condition information at a patient's first visit at the clinic or t can be a digital dental chart already populated with such information at one or more previous visits at the clinic. The digital dental chart can have standardized representations of the patient's teeth as the one illustrated inFIG.1.

In step216the obtained digital dental chart is populated with the derived tooth condition information. When the information has been derived from diagnostic data which are spatially correlated with the digital 3D representation, i.e. the spatial correlation of the diagnostic data and the shape data of the digital 3D representation is known, the derived information can immediately be projected onto the corresponding regions of the digital dental chart. If this spatial correlation is not established it is also possible for the operator to manually annotate the derived information on the digital dental chart e.g. using a computer mouse to indicate where on a tooth region of the dental chart the tooth condition information should be added. If gingiva condition information, such as presence of inflammation or pocket depth, has been derived from the diagnostic data this information can also be added to the digital dental chart.

Steps211to214alone relates a method for deriving tooth condition information while steps211to216relates to a method for deriving the tooth condition information and populating a digital dental chart with the derived information.

The steps can be performed by a system having a non-transitory computer readable medium capable of receiving and storing the digital 3D representation of the patient's teeth, the diagnostic data for one or more of the teeth, and the digital dental chart. A computer program product is also stored on the medium where the computer program product has instructions for deriving the tooth condition information and for populating the digital dental chart with the derived tooth condition information. The graphical representation of the populated digital dental chart can be displayed on a display unit of the system. Such a system described in relation toFIG.4.

FIGS.3A,3B,3C and3Dillustrate steps for deriving tooth condition information and populating a digital dental chart with the derived information.

FIG.3Ashows a schematic of an obtained digital 3D representation320. The digital 3D representation can be visualized in a digital work space presented to the operator on a display such as a computer screen. The digital 3D representation320has shape data for the surfaces of part of the gingiva321and the six anterior teeth of the patient's upper jaw, i.e. teeth #6 to #11 in the Universal tooth numbering system. In addition to the shape data expressing the topography of the teeth the digital 3D representation320also provides diagnostic data in the form of fluorescence data. The fluorescence data has significantly stronger intensities in two sections322on the patient's maxillary central incisor324and maxillary lateral incisor325. The fluorescence data can e.g. be from fluorescence emitted at wavelengths above 600 nm from porphyrin compounds when these are excited by light at 405 nm. As described above porphyrin compounds indicate that cariogenic bacteria are present.

The digital 3D representation can be obtained by an intra-oral scanner using a blue LED to illuminate the patient's teeth. The topography of the teeth can be derived from the blue light reflected from the teeth surface while tooth condition information is derived from the red light emitted by fluorescent materials in the infected regions322in response to the blue light. This provides that the fluorescence data, i.e. the diagnostic data, are obtained simultaneously with the shape data and that the 25 fluorescence data are part of the digital 3D representation and according are spatially correlated with the shape data for the teeth.

FIG.3Bshows the obtained digital 3D representation320with the maxillary central incisor segmented from the digital 3D representation. The segmented portion forms a digital model327of the maxillary central incisor (tooth #8) shown as a dotted line in the figure. The segmentation of the teeth from the digital 3D representation involves a detection of the boundaries of the surfaces for each tooth. The boundary at the gingiva can be detected based on the shape data of the digital 3D representation or on color data of the digital 3D representation. The segmentation can be performed by a computer program product having instructions configured for detecting the boundaries in the digital 3D representation or by an operator marking the boundaries on the digital 3D representation. The boundaries detected by the computer algorithm can also be visualized in a digital work space such that the operator can verify that the detected boundaries are correct. The individual teeth are identified using a computer program product configured for making the identification from the digital 3D representation. This can be realized based on an analysis of the shape of the segmented teeth and/or by a comparison with templates teeth describing standard shapes and relative sizes of the teeth. If the digital 3D representation has shape data for the central incisors these can be detected based on their symmetry and the remaining teeth identified based on their natural position relative to the central incisors. InFIG.3Bthe segmented tooth is identified as tooth #8 using the Universal tooth numbering system. Instead of using a computer program product the operator can manually identify each tooth using e.g. a pointing tool in connection with the digital work space.

When the fluorescence data are obtained as part of the digital 3D representation the spatial correlation between the fluorescence data and the shape data is known. If the analysis of the fluorescence data concludes that the fluorescent signal recorded from some sections of the teeth, such as sections322at the incisal edges of the maxillary central incisor324and maxillary lateral incisor325, is significantly stronger than the fluorescent signal from other parts of the teeth it is concluded that there is a risk that cariogenic bacteria are present in these sections. I.e. based on the fluorescence data the system or the operator derives the tooth condition information that caries probably is present or developing in sections322on the maxillary central incisor324and maxillary lateral incisor325. The derived information is visualized using a symbol330on the digital model of the segmented tooth327as illustrated onFIG.3C.

FIG.3Dshows symbols330,331for the tooth condition derived for the maxillary central and lateral incisors projected onto the corresponding regions of a digital dental chart332like the one described inFIG.1. The thereby populated digital dental chart can be stored and examined e.g. at the next visit at the dental clinic to determine what has changed since the last visit.

FIG.4shows a schematic of a system according to an embodiment. The system440comprises a computer device441comprising a computer readable medium442and an electronic data processing device in the form of a microprocessor443. The system further comprises a visual display unit444, and at least one access device and/or interface that allow the operator to utilize the functionality of the computer system. The access device and/or interface can include but is not limited to a keyboard, mouse, touch screen, stylus, joystick, light pen, trackball, voice interactive function, three-dimensional glove, solid three-dimensional mouse ball, graphical user interface (GUI), display screen, printer, and other known input or output devices and interfaces. InFIG.4the access devices are a computer keyboard445and a computer mouse446for entering data and activating virtual buttons of a user interface visualized on the visual display unit444. The visual display unit444can e.g. be a computer screen. The computer device441is capable of obtaining a digital 3D representation of the patient's teeth and diagnostic data which both can be stored in the computer readable medium442and loaded to the microprocessor443for processing. The digital 3D representation can be obtained from a 3D color scanner450, such as the TRIOS 3 intra-oral scanner manufactured by 3Shape TRIOS A/S, which is capable of recording both shape and color of the teeth.

The computer system provides for the execution of the method steps by which the acquired digital 3D representation can be manipulated, either automatically or in response to operator commands. The computer may be a general purpose computer capable of running a wide variety of different software applications or a specialized device limited to particular functions. In some embodiments, the computer is a network or other configuration of computing devices. The computer may include any type, number, form, or configuration of processors, system memory, computer-readable mediums, peripheral devices, and operating systems.

In one embodiment, the computer includes a personal computer (PC), which may be in the form of a desktop, laptop, tablet PC, or other known forms of personal computers. Diagnostic data can be recording using different types of diagnostic devices451, such as an Infrared scanner and a CBCT scanner for recording infrared and data CBCT data, respectively. The recorded data are loaded into the computer readable medium442and analyzed using the microprocessor443to derive the tooth condition information for the patient's teeth.

A digital dental chart containing previously recorded data for the patient is stored on the computer readable medium442from where it can be loaded into the microprocessor443and visualized on the visual display444unit such that the dentist can recall the dental history of the patient.

The system441is configured for allowing an operator to arrange the digital 3D representation and the diagnostic data according to the spatial arrangement which best reflects to anatomical correct arrangement. This is relevant when the spatial correlation between the digital 3D representation and the diagnostic data is needed but not known. This can e.g. be the case when the diagnostic data are CBCT data which has been recorded independently of the digital 3D representation. The digital 3D representation and the diagnostic data can be moved relative to each other in three dimensions using e.g. a computer mouse to drag or rotate visualizations of the digital 3D representation and the diagnostic data on the visual display unit444. When the operator is satisfied with the relative arrangement he activates a virtual push button in the user interface and the spatial relationship is stored in the computer readable medium442.

Stored on the computer readable medium442is also computer program product having instructions for analyzing the diagnostic data to derive tooth condition information for the patient's teeth.

The computer readable medium442further stores a computer program product for the segmenting of teeth from the digital 3D representation and the identification of the individual teeth. When applied to the digital 3D representation the result is digital models of the individual teeth where the corresponding teeth numbers are known. These digital models of the individual teeth can be stored together with the digital dental chart in the patient's electronic journal on the computer readable medium442and be re-used at the next visit for the identification of individual teeth in a digital 3D representation recorded at the next visit.

When the spatial correlation between the digital 3D representation and the diagnostic data is know it is also known which tooth or teeth a given tooth condition information is derived for. Once the tooth condition information is derived it can thus be projected onto the digital dental chart visualized in the visual display unit444. Thereby the dentist will have a useful tool for evaluating the patient's dental situation and to determine which treatments can be applied to correct for any problems.

FIG.5shows a schematic of a digital work space of a digital environment according to an embodiment.

In a first part557of the digital workspace555a segmented tooth527from a digital 3D representation is illustrated. Tooth condition information530has been derived from obtained diagnostic data and is visualized on the segmented tooth. A digital dental chart560is also seen in the first part557of the digital workspace555. When the operator has confirmed the derived tooth condition information a symbol for the information can be projected onto the digital dental chart560by activating the virtual push button561. The virtual push button can e.g. be activated using a computer mouse button. The same mouse button can also be used for adjusting the position of the symbol on the region of the digital dental chart representing the tooth if the operator desires to do so.

The second part558of the digital workspace comprises data entering sections562,563e.g. for entering the dentist's comments relating to the patient's dental situation, for selecting which diagnostic data to analyze and for choosing the digital dental chart which the tooth condition information is to be recorded on.

The digital workspace can be visualized on a visual display unit, such as a computer screen being part of a system configured for implementing the disclosed method.

The digital environment and workspace illustrated inFIG.5comprises one or more digital tools which can be displayed in the digital workspace. These digital tools allowing the operator to interact with the digital environment e.g. by entering data and to be part in at least one of the steps of identifying, segmenting, deriving and correlating. InFIG.5one of these tools is embodied as the virtual push button561.

When activated the virtual push button causes the execution of instructions for populating the digital dental chart with the derived tooth condition information. Digital tools for segmenting and identifying the individual teeth from the digital 3D representation can be embodied by instructions of a computer program product allowing for an automatic segmentation and identification of the teeth.

Although some embodiments have been described and shown in detail, the invention is not restricted to them, but may also be embodied in other ways within the scope of the subject matter defined in the following claims. In particular, it is to be understood that other embodiments may be utilized and structural and functional modifications may be made without departing from the scope of the present invention.

In device claims enumerating several means, several of these means can be embodied by one and the same item of hardware. The mere fact that certain measures are recited in mutually different dependent claims or described in different embodiments does not indicate that a combination of these measures cannot be used to advantage.

A claim may refer to any of the preceding claims, and “any” is understood to mean “any one or more” of the preceding claims.

It should be emphasized that the term “comprises/comprising” when used in this specification is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps, components or groups thereof.

The features of the method described above and in the following may be implemented in software and carried out on a data processing system or other processing means caused by the execution of computer-executable instructions. The instructions may be program code means loaded in a memory, such as a RAM, from a storage medium or from another computer via a computer network. Alternatively, the described features may be implemented by hardwired circuitry instead of software or in combination with software.