METHOD FOR PROVIDING DENTAL MOUTHPIECE HAVING SPACE FOR MEDICINE AND METHOD FOR USING SAME

Abstract

A method of providing a dental mouthpiece comprises: an oral cavity shape acquisition step for acquiring the shape of the oral cavity; a design requirement specification step of receiving a selected range and an amount of a medicine as design requirements; and a design step for outputting design on the basis of the shape of the oral cavity and the range and amount of application of the medicine, design data of a dental mouthpiece that is provided with a space for the medicine and is able to retain the above-mentioned amount of the medicine in the application range.

Claims

1. A method for providing a dental mouthpiece, comprising: an intraoral shape acquisition step for acquiring an intraoral shape; a design requirement specification step, which accepts a specification of a range and an amount of medicine application as a design requirement; and a design step of outputting design data of a dental mouthpiece with a space for medicine capable of retaining the amount of medicine within the application range based on the intraoral shape, the application range, and the amount.

2. A method for providing a dental mouthpiece, comprising: an intraoral shape acquisition step for acquiring an intraoral shape; a design requirement specification step to specify a range and a amount of medicine to be applied as a design requirement; and a design step using a computer to output design data for a dental mouthpiece with a space for medicine capable of retaining the amount of medicine within the application range based on the intraoral shape, the application range and the amount.

3. The method for providing the dental mouthpiece according to claim 1, wherein the method further comprising a manufacturing step of manufacturing the dental mouthpiece based on the design data output.

4. A method for using a dental mouthpiece, comprising: a step of applying the amount of the medicine to the space for the medicine in the dental mouthpiece produced by the method of claim 3 and wearing it in an oral cavity for a predetermined period of time.

5. A method for using dental mouthpieces for a first dental mouthpiece and a second dental mouthpiece manufactured by the method of claim 3 based on a first design requirement and a second design requirement, respectively, comprising: a first step of applying the amount of the medicine according to the first design requirements to the space for said medicine of the first dental mouthpiece during a first period of time, and placing the medicine in the oral cavity; and a second step of applying said amount of said medicine according to said second design requirement to said space for said medicine in said second dental mouthpiece and placing said medicine in the oral cavity during a second period of time.

6. A method for using dental mouthpieces according to claim 5, wherein the first dental mouthpiece has a space for the medicine in a narrow area that includes the affected bleeding area, and the second dental mouthpiece has a space for the medicine in a strip along the cervical gingival line over a larger area that includes the affected bleeding area.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] FIG. 1A is a block diagram showing the overall configuration of system 1.

[0017] FIG. 1B is a block diagram showing the hardware configuration of the design device 20.

[0018] FIG. 1C is a block diagram showing the functional configuration of the design device 20.

[0019] FIG. 2 is a flowchart showing a method of providing a dental mouthpiece with a space for medicine.

[0020] FIG. 3A is a drawing showing the process of designing a dental mouthpiece with space for medicine.

[0021] FIG. 3B is a drawing showing the process of designing a dental mouthpiece with a space for medicine.

[0022] FIG. 3C is a drawing showing the process of designing a dental mouthpiece with a space for medicine.

[0023] FIG. 4A is a drawing showing the process of designing a dental mouthpiece with a space for medicine.

[0024] FIG. 4B is a drawing showing the process of designing a dental mouthpiece with a space for medicine.

DETAILED DESCRIPTION OF THE EMBODIMENT

[0025] The following is a detailed description of specific embodiments in which the invention is applied, with reference to the drawings.

[0026] FIG. 1A is a block diagram of the system 1 used in the method of providing dental mouthpieces.

[0027] System 1 includes an intraoral shape acquisition device 10, a design device 20, and a manufacturing device 30.

[0028] The intraoral shape acquisition device 10 is a device for measuring the intraoral shape of a patient and acquiring a three-dimensional model thereof. The intraoral shape can be obtained, for example, by a 3D scan of the mouth, a 3D scan of a dental model, or by constructing a 3D model from a 2D image. The three-dimensional shape of the oral cavity that can be obtained by these methods is referred to in this paper as a three-dimensional model or simply a model. This model is typically three-dimensional point cloud data. Alternatively, the model may be three-dimensional polygon data or CAD data.

[0029] For example, IOS (Intra Oral Scanner (IOS), can capture images of a patient's oral cavity using a reader called a wand and output the intraoral shape as digital data. The wand emits light to objects in the mouth (teeth, gums, etc.) and detects the reflected light with a sensor to acquire point cloud data (models) that show the three-dimensional shape of the mouth.

[0030] Alternatively, the model may be obtained by creating a dental model (a model of a tooth shape, typically a plaster model, etc.) by intraoral impression and scanning the dental model using a general-purpose 3-D scanner or similar device.

[0031] Alternatively, the model may be constructed based on 2D images of the oral cavity or dental model taken by an optical camera, or 2D images of the oral cavity obtained by CT scan or radiography. For example, a known method of constructing a three-dimensional model based on multiple two-dimensional images taken from different angles can be employed.

[0032] Thus, the intraoral shape acquisition device 10 includes, for example, devices such as an IOS, a general-purpose 3D scanner, and a camera. Alternatively, an information processing device such as a smartphone, PC (personal computer), etc., which is pre-equipped with a scanner, camera, etc., or attached with these devices later, may be employed as the intraoral shape acquisition device 10. The latter type of device may include, for example, a smartphone with an attachment having the same functions as the IOS.

[0033] The design device 20 is an information processing device for designing dental mouthpieces. The design device 20 inputs the model output by the intraoral shape acquisition device 10, accepts various operations by the user (a dentist), and outputs design data for dental mouthpieces according to a predetermined procedure. The process is performed. The design data is data that defines the shape of the dental mouthpiece and is typically 3D CAD data. The design data is read by the manufacturing device 30 described below and used to manufacture the dental mouthpiece. The design data is not limited to 3D CAD data, but can be data in any format that can describe a 3D shape.

[0034] FIG. 1B is a block diagram showing the typical hardware configuration of the design device 20. The design device 20 includes a CPU (Central Processing Unit) 201, volatile memory 203, nonvolatile memory 205, bus 207, interface 209, and an input/output device 211.

[0035] The CPU 201 reads the program stored in nonvolatile memory 205 via bus 207 and executes information processing according to the program to realize the specific functions. In this embodiment, the CPU 201 is used to execute a 3D CAD application.

[0036] Nonvolatile memory 205 is a storage device that retains its memory state regardless of the power supply status of the design device 20, such as a hard disk or SSD, etc. Generally, programs and data stored in nonvolatile memory 205 are extracted to volatile memory 203 during program execution.

[0037] The volatile memory 203 is a storage device that stores programs and data extracted from the nonvolatile memory 205, as well as temporary calculation data and data input or output via the input/output device 211.

[0038] Input/output device 211 includes data output devices such as displays, data input devices such as keyboards and pointing devices, and communication interfaces that control communication with external parties. Display data output from the CPU 201 is displayed on the display through the interface 209. Commands and data input from the keyboard and pointing device are passed via the interface 209 to the CPU 201. The communication interface obtains the transmission data output by CPU 201 from interface 209 and outputs it to the external device. The communication interface also requires received data from the external device and passes it to the CPU 201 via interface 209. In this embodiment, the CPU 201 of the design device 20 is used to acquire the intraoral shape via the communication interface to acquire a model of the patient's intraoral shape from the intraoral shape acquisition device 10. The 3D CAD application then processes the model according to user operations accepted by the data input device to generate 3D CAD data of the dental mouthpiece. The CPU 201 transmits the 3D CAD data to the manufacturing device 30 via the communication interface.

[0039] The design device 20 is typically a stand-alone information processing device, such as a PC (Personal Computer), smartphone, tablet, etc. However, the invention is not limited to this and may be realized by any information processing resource, such as distributed processing servers, cloud computing, edge computing, fog computing, etc.

[0040] FIG. 1C is a block diagram showing the functional configuration of the design device 20. The design device 20 has a model acquisition section 21, a dental mouthpiece design section 22, a space specification section for medicine 23, design condition specification section 24, space for space design section for medicine 25, and design data output section 26. The specific operations of each of these processing sections are described below.

[0041] The manufacturing device 30 is a device that molds and outputs dental mouthpieces based on the design data (typically 3D CAD data) output by the design device 20. For example, 3D printers, press molding machines, injection molding machines, and shaving molding machines are known as devices with such functions.

[0042] FIG. 2 is a flowchart showing the method of providing a dental mouthpiece.

[0043] Step 1 (S1): Measure Intraoral Shape

[0044] The intraoral shape acquisition device 10, operated by a dentist, measures the intraoral shape of the patient. The intraoral shape acquisition device 10 outputs a model of the patient's intraoral shape.

[0045] Step 2 (S2): Determine Design Requirements for Dental Mouthpiece

[0046] The dentist observes the condition of the affected area, etc., and formulates a treatment plan based on dentist's findings. In other words, the dentist determines the type of medicine to be administered to the patient, the dosage (volume of medicine), the site of administration (application), and the administration schedule.

[0047] The following is an example of a treatment plan formulated by a dentist.

[0048] Findings: Periodontal disease. Inflammation with bleeding.

[0049] Treatment strategy: First, apply antibiotics to the site of bleeding (phase 1).

[0050] The dose (volume) of medicine X to be applied is D1 ml. If the inflammation has subsided, apply the disinfectant to a larger area than in phase 1, including the area that was bleeding (phase 2). The dose (volume) of medicine Y to be applied is D2 ml.

[0051] In this example, multiple dental mouthpieces would be created as the treatment phase progresses; one for use in phase 1 and one for use in phase 2. The dental mouthpiece used in the first phase will have a space for the medicine with a capacity of at least D2 near the bleeding site. The mouthpiece used in the second phase has a more extensive space for the medicine with a capacity of at least D2. For example, a strip of space for the medicine is formed along the cervical gingival line at and around the bleeding site.

[0052] Step 3 (S3): Design a Dental Mouthpiece

[0053] The design device 20, operated by the dentist, inputs the model output in step 1 and outputs the design data for the dental mouthpiece. With reference to FIG. 1C, the operation of the design device 20 in step 3 is described.

[0054] The model acquisition unit 21 accepts input of the model (typically 3D point cloud data) generated by the design device 20 in step 1.

[0055] The dental mouthpiece design section 22 provides a design data for a dental mouthpiece without a space for medicine (typically 3D CAD data) based on the model obtained by the model acquisition unit 21. Methods for automatically or semi-automatically designing dental mouthpieces in general, i.e., without spaces for medicines, based on models are well known in the past. For this reason, a detailed explanation is omitted here.

[0056] The space specification section for medicine 23 accepts the user's (dentist's) instructions as to where on the dental mouthpiece the space for the medicine should be located and in what shape. In other words, it accepts instructions from the user regarding the range of application of the medicine. For example, the space specification section for medicine 23 displays on the screen the 3D CAD data of the dental mouthpiece created by the dental mouthpiece design unit 22 and accepts the area designation operation for the CAD data. The solid lines in FIG. 3A and FIG. 4A show the 3D CAD data of the dental mouthpiece displayed on the screen. Here, the dentist operates the pointing device to draw an arbitrary closed figure on the surface of the dental mouthpiece (hereinafter referred to as “region”, shown as a dashed line in the figure). This designates the closed area indicated by the dashed line as the area that shows the location of the space for the medicine and its shape.

[0057] FIG. 3A shows an example of the user designating an area to provide space for the medicine in a narrow area that includes the bleeding area in order to create a dental mouthpiece for use in the first phase of the treatment strategy described above. FIG. 4A shows an example of a user designating an area to provide space for medicine in a wide area, including the bleeding area, in a band along the cervical gingival line for use in the second phase of the treatment strategy described above.

[0058] The method disclosed here is only an example, and other methods may be used to specify the position and shape of the space for the medicine. For example, instead of 3D CAD data of a dental mouthpiece, the space specification section for medicine 23 may display a 3D model of the intraoral shape on the screen and accept area specification for this model. Alternatively, the area designation may be accepted by having the user trace the surface of the dental model with a digitizer or a pen with a probe, and acquiring the trajectory of the pen tip. Instead of having the user draw a figure using a pointing device as described above, the position and shape of the area may be specified by having the user input information such as coordinates and size from a pointing device or keyboard. For example, if you want the user to specify a closed circular region of radius R centered at an arbitrary point P on the surface of the 3D CAD data of a dental mouthpiece or intraoral shape, the coordinates of point P and the value of radius R can be input from a pointing device or keyboard.

[0059] In the above example, the user (dentist) directly specifies the location and shape of the space for the medicine, but instead of or as an auxiliary for this, an interface may be provided that allows the user (dentist) to indicate the location and shape of the space for the medicine more broadly. In this case, the space specification section for medicine 23 calculates the specific position and shape of the space for medicine in response to the user's abstract instructions. For example, the space specification section for medicine 23 presents the user with choices such as “maxillary anterior teeth, maxillary left back teeth, maxillary right back teeth, mandibular anterior teeth, mandibular left back teeth, mandibular right back teeth” to roughly specify the area where the space for the medicine is formed. The space specification section for medicine 23 automatically determines the position and shape of the space for the medicine according to the result of the user's selection. To perform this process, the space specification section for medicine 23 shall have logic to determine the appropriate location and shape of the space for medicines based on the results of the user's selection. For example, when “front teeth” is selected, the area with a predetermined offset around the cervical gingival line is set for teeth #1 to #3, and when “back teeth” is selected, the area is set for teeth #4 to #8. The user can specify the space for the medicine in the “Space Designation” section. The user may accept the area proposed by the space specification section for medicine 23 as it is, or may modify the proposed area accordingly.

[0060] The design condition specification section 24 accepts input of the amount of medicine to be applied to the space inside the dental mouthpiece for the medicine. Here, the user can enter the dosage determined in step 2 as a numerical value. In the example of the treatment plan described above, the user enters the volume D1 of medicine X when creating the dental mouthpiece to be used in the first phase, and the volume D2 of medicine Y when creating the dental mouthpiece to be used in the second phase.

[0061] In the above example, the user (dentist) specifies the dosage of the medicine by a numerical value. As an alternative or a ways to assist with this, a function may be provided whereby the user selects a case, etc., and the design condition specification section 24 automatically calculates the dosage of the medicine according to the selected case, etc. For example, the design condition specification section 24 presents the user with one of the options such as “A, B, C . . . ” indicating the level of progression of periodontal disease. When the user selects the progression level, the design condition specification section 24 determines or suggests (i.e., displays to the user) the appropriate dosage of the medicine according to the progression level. In this case, it is assumed that the design condition specification section 24 maintains in advance a rule (table, etc.) that maps cases, etc. to the appropriate dosage of the medicine. The user may accept the dosage suggested by the design condition specification section 24 as it is, or may modify the suggested dosage in light of circumstances such as the affected area being reddish or having a lot of tartar.

[0062] The space design section for medicine 25 calculates the volume V of the void bounded by the area designated by the space specification section for medicine 23, the patient's teeth and gingiva, and the space for medicine. In other words, it calculates the size of the space between the patient's teeth at the location where the space for medicine is to be provided. In general, the size of the interdental space varies from region to region, e.g., whether it is anterior or molar teeth, and also from patient to patient. Therefore, the system 1 can calculate the void V in the area specified by the dentist based on the patient-specific intraoral shape model and create a medicine space with an appropriate volume according to the void V.

[0063] The space design section for medicine 25 compares the volume V of the void with the volume D of the medicine to be applied, which is obtained by the design condition specification section 24. If D>V, the space design section for medicine 25 calculates the difference DIFF (=D−F). Then, a portion of the 3D CAD data of the dental mouthpiece is deformed to form at least a volume DIFF to form a medicine space with DIFF in the designated area. Typically, the shape of the dental mouthpiece is inflated labially, buccally, or lingually in the designated area to form the medicine space (FIG. 3B, FIG. 4B). In this case, the designated range may be fully expanded, or it may be formed so that it gradually rises from the outer edge of the designated range to the center. By doing the latter, discomfort when wearing the dental mouthpiece can be suppressed (FIG. 3C cross-section view according to A-A′ of FIG. 3B).

[0064] If D<V, i.e., the volume of medicine D is smaller than the void V, there is a possibility that not enough medicine will be distributed to the area where the medicine is to be applied. In this case, the space design section for medicine 25 may issue a warning and recommend, for example, that the dosage of the medicine be reviewed.

[0065] The design data output section 26 outputs the design data (typically 3D CAD data) created by the space design section for medicine 25 to the manufacturing device 30.

[0066] Step 4 (S4): Manufacture a Dental Mouthpiece

[0067] The manufacturing device 30 obtains the design data output by the design data output section 26 in step 3. The manufacturing device 30 uses a biocompatible transparent resin or other material, such as resin, to mold and output dental mouthpieces according to design data. For example, dental mouthpieces can be manufactured by 3D printing, press molding, injection molding, machining molding, etc.

[0068] Step 5 (S5): Provide Dental Mouthpiece

[0069] A mouthpiece is provided to the patient. The patient is treated by wearing a dental mouthpiece with a space formed for medicine for a period of time and duration indicated by the dentist. The patient wears the mouthpiece while sleeping, for example, over a period of one week. Before each wearing, a medicine prescribed by the dentist (e.g., a paste containing herbal medicine) is applied to the space for the medicine in the dental mouthpiece. If the wearing period indicated by the dentist has expired, the patient follows the dentist's new instructions. For example, a newly designed dental mouthpiece may be provided to implement the next phase of treatment, or treatment may be terminated.

[0070] This embodiment can provide a dental mouthpiece with an optimally sized space for medicine according to the condition of the affected area and the shape of the patient's oral cavity. This ensures that the appropriate amount of medicine is brought into contact with the affected area and that the medicine is held in such a way that it does not flow out. In particular, when the amount and range of medicine application is to be varied according to the progress of treatment, providing multiple dental mouthpieces of different designs in stages makes it possible to administer the appropriate medicine in accordance with the treatment plan.

[0071] The present invention is not limited to the above-mentioned embodiments but can be modified as appropriate to the extent not to depart from the purpose of the invention. For example, in the above embodiment, the user (dentist) specifies the volume of the medicine, but other physical quantities or units may be specified instead of the volume of the medicine. In this case, the design condition specification section 24 calculates the volume of the medicine from the physical quantity, units, etc. entered. For example, if the specific gravity of the medicine is known, the weight of the medicine can be specified, and the design condition specification section 24 can convert it to the volume of the medicine. Or, if the weight of the active ingredient per unit volume is known, the weight of the active ingredient may be specified and converted to the volume of the medicine by the design condition specification section 24.

[0072] In the above example, it is mainly assumed that the dentist designs and manufactures the dental mouthpiece, but the present invention is not limited to this. For example, the dentist performs steps S1 through S3, and the manufacturing step in step S4 and thereafter can be performed by the patient at home or elsewhere. A 3D printer or the like may also be used to perform this step. Alternatively, the laboratory that receives the design data may perform the manufacturing in step S4 and deliver the completed dental mouthpiece to the patient. According to this method, for example, a patient undergoing treatment using multiple dental mouthpieces of different designs in stages can obtain a dental mouthpiece for a new phase without having to visit a dental clinic each time. Thus, the patient can continue treatment with less burden.

[0073] In the above-mentioned embodiment, it is assumed that the dentist performs steps S1 through S3. However, this is not limited to this, and any assistants or subcontractors may perform steps S1 through S3 based on the dentist's instructions.

[0074] The above-mentioned embodiments mainly disclosed a method of providing a dental mouthpiece intended for the treatment of periodontal disease and the like. However, the invention is not limited to this and can be applied to dental mouthpieces for any other use. For example, it can be applied to cosmetic and aesthetic applications such as periodontal disease prevention treatments and whitening. In this case, the steps that were performed by the dentist in the abovementioned forms can be performed by a dental hygienist or other practitioner.

DESCRIPTION OF REFERENCE NUMERALS

[0075] 1 system

[0076] 10 Intraoral shape acquisition device

[0077] 20 Design device

[0078] 30 Manufacturing device

[0079] 201 CPU

[0080] 203 Volatile memory

[0081] 205 Nonvolatile memory

[0082] 207 Bus

[0083] 209 Interface

[0084] 211 Input/output device

[0085] 21 Model Acquisition Section

[0086] 22 Dental Mouthpiece Design Section

[0087] 23 Space specification section for medicine

[0088] 24 Design condition specification section

[0089] 25 Space design section for medicine

[0090] 26 Design data output section