WO2016197326A1 - 一种颜颚手术影像校正设计系统及方法 - Google Patents
一种颜颚手术影像校正设计系统及方法 Download PDFInfo
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Definitions
- the invention relates to a system and method for image correction design of a face-lift surgery, in particular to an image correction design system and method for dental, orthodontic and face-finish surgery.
- One of the well-known Orthognathic Surgery is to correct the structural and developmental problems of the ankle and face or to improve sleep apnea, TMJ disorders, and bone problems. Malocclusion, or other dentition correction problems that are not easily accomplished with orthodontic appliances; this procedure is also often used to treat congenital cleft lip and palate.
- Physician performing a sinus surgery on the patient requires the original bone to be cut and adjusted, and then the bone and the bone nail are used to join the bone and shape.
- the doctor needs to go through an X-ray machine or a computerized tomography. Scan the CT diagnostic image to confirm the expected location of the operation, and then perform the dental mold preparation and the surgical site check according to the doctor's experience.
- the doctor in order to facilitate the fixation of the ankle or bone during the operation, the doctor usually needs to use the medical bone plate. Screws, bone nails, stainless steel wires and other materials will fix and shape the structure of the patient's ankle and face.
- Correct imaging data to give the doctor a preoperative evaluation or confirmation of postoperative healing Usually, the surgeon can only perform the surgery according to the photos taken at the current situation and the experience accumulated by the doctor over the years. The distortion of the photograph is possible. Will result in inaccurate judgment of the surgical site and prolong the operation time, and can not be real-time in the postoperative correction treatment Physicians provide a basis for tracking healing and preoperative evaluation. It may also cause loss of occlusion or misalignment such as incorrect occlusion or excessive occlusion. Therefore, the experience and skills of the physician often become the success or failure of the above surgery. Key factor.
- Taiwan patent I367745 Method for planning the correct surgical plan with the analysis of the best symmetry plane of Yan Yan
- the humerus bone image was scanned by computerized tomography, and the patient's gypsum tooth model was used to establish the coordinate relationship corresponding to the upper and lower tibia image models, so that the coordinates of the two were aligned, and then the spatial positioning tracking system was used.
- the sacral surgery plan can be pushed from the two-dimensional cranial analysis to the three-dimensional cranial symmetry.
- Taiwan patent I397402 “Integration method for implant orientation and dental drill guide plate design” is an integrated method for the design of a dental implant orientation and dental implant guide plate design, using patients
- the computed tomography image reconstructs a sacral image model and combines with the patient's individual dynamic occlusal surface.
- the dynamic occlusal surface determines the preferred entry point of the implanted implant, or the cross section of the sacral image model is used to calculate the appropriate
- the implant entry point and the end point are determined, the implant entry point and the end point are determined, and the implant can be transferred to the implant drilling guide plate to establish the operation, and the implant drilling guide plate is designed to consider interference.
- a conventional Taiwan patent I385606 "Positioning correction method for a toothed solid model and a jig thereof" is a positioning correction method for a gingival solid model, comprising a selection step, a scanning step, a manufacturing step, and a placing step , a positioning step, and a correction step.
- a jig is formed according to the foregoing steps, and is set on a corresponding tooth of a model to be corrected, with a positioning system, a positioning plate, and a mounting Positioning the marked handheld positioning machine to perform positioning correction.
- positioning correction can be performed individually for each tooth, but the prior patent still cannot accurately scan the bone image and provide positioning so as not to provide postoperative healing and preoperative evaluation.
- the main object of the present invention is to provide a method for correcting image correction of a face-lift surgery, which can be used for dental, orthodontic and face-finishing surgery, and performs a scan image correction comparison method according to the image correction design method of the present invention.
- Procedures that shorten dental and orthodontic surgery and simulate surgery The human bone skeleton features are used to achieve accurate positioning and stable combination of bones and corrective instruments after surgery.
- Another main object of the present invention is to provide a color correction imaging image correction design system, which has a scanning image correction comparison module, and the image data of the first scanned image data module and the second scanned image data module The imaging data of the group is corrected and compared, and the image correction design system of the sputum surgery can accurately position the scalpel before the operation and accurately locate the fixation of the fixed plate and the bone after the operation.
- the implementation technology of the present invention is as follows: a method for image correction design of a face surgery operation, the method comprising the steps of: inputting a first scanned image data, wherein the first scanned image data is a scanned skeleton and a tooth And the soft tissue relative coordinate position image data; and then inputting the second scan image data, the second scan image data is scanning the image data of the patient's plaster dental mold; performing a scan image correction alignment step, the first scan image data Performing correction alignment and archiving with the second scanned image data; performing image block calculation steps, performing layer management and cutting block display on the archive; performing a surgical simulation image design step, and managing the layer and The archive displayed by the cutting block is input to execute a surgical data parameter for designing the surgical simulation image file creation; and an output step of outputting the surgical analog image file by using a display device.
- the method for image correction of the sputum surgery image further comprises an image data conversion step of converting the first scanned image data and the second scanned image data into a three-dimensional data image file.
- the method for correcting image correction of the image is further characterized in that after the step of inputting the first scanned image data, an image data conversion step is further included, and the first scanned image data is converted into a three-dimensional (3D) data image file.
- an image data conversion step is further included, and the first scanned image data is converted into a three-dimensional (3D) data image file.
- the method for correcting image correction of the eyelid surgery image wherein the three-dimensional data file format is a three-dimensional (3D) mechanical design STL archive.
- the method for correcting image correction of the eyelid surgery wherein the first scanned image data is a computed tomography file (referred to as a CT file).
- a computed tomography file referred to as a CT file
- the method for correcting image correction of the eyelid surgery image wherein the second scanned image data is an image data of the patient's plaster dental mold scanned by a precision grating instrument.
- the method for correcting image correction is performed, wherein after the scanning image correcting step, a noise removing step is further included to clear the archive noise.
- the method for correcting image correction of the eyelid surgery further comprises a bone plate correction step,
- the surgical simulation image file is checked against the bone plate correction step.
- the method for correcting image correction of the eyelid surgery wherein the step of correcting the bone plate comprises a surgical guiding bone plate correcting step and a fixed bone plate correcting step.
- the surgical guiding bone plate correcting step is to provide a surgical cutting area correction and a surgical guiding bone plate accurate alignment correction.
- the fixed bone plate correction step is to accurately position the bone and correct the position of the bone for the fixed bone plate for providing postoperative bone healing.
- the method for correcting image correction of the eyelid surgery wherein the surgical data parameter is a moving distance of the skeleton bone, a surgical cutting angle or a bone overlapping portion.
- the method for correcting image correction of the eyelid surgery wherein the display device is a liquid crystal screen, a tablet computer, a PDA or a smart phone.
- a color correction surgical image correction design system comprising: a first scanned image data module, wherein the first scanned image data module is scanned to obtain a color ⁇ bone and tooth and soft tissue relative coordinate position image data; second scan image data module, the second scanned image data module is for scanning the image data of the patient's plaster dental mold; a scanning image correction comparison module, the first The image data of the scanned image data set is compared with the image data of the second scanned image data module for comparison and archiving; and an image block computing module performs layer management and cutting block display on the archive;
- the surgical simulation image design module inputs the image of the layer management and the cutting block display, inputs a surgical data parameter for designing the surgical simulation image file, and an output module to simulate the operation image.
- the image file is output using a display device.
- the image processing system for image processing includes an image data conversion module, and converts the image data of the first scanned image data module and the image data of the second scanned image data module into three dimensions ( 3D) data file.
- an image data conversion module converts the image data of the first scanned image data module and the image data of the second scanned image data module into three dimensions ( 3D) data file.
- the image processing module of the first scan image data module further includes an image data conversion module, and converts the image data of the first scanned image data module into three-dimensional (3D) Data file.
- an image data conversion module converts the image data of the first scanned image data module into three-dimensional (3D) Data file.
- the facial surgery image correction design system wherein the three-dimensional data file format is a three-dimensional (3D) mechanical design STL file.
- the facial surgery image correction design system wherein the first scanned image data module
- the image data is a computed tomography file (referred to as a CT file).
- the image processing data of the second scan image data module is that the image data of the patient's plaster dental mold is scanned by a precision grating instrument.
- the image processing correction design system further includes a noise clearing module in the scanned image correcting module for clearing the archive noise.
- the facial surgery image correction design system further comprises a bone plate correction module, and the surgical simulation image file is checked with the bone plate correction module data.
- the facial surgery image correction design system comprises a surgical guide bone plate correction module and a fixed bone plate correction module.
- the surgical guiding bone plate correction module is provided for correcting the surgical cutting area and correcting the alignment of the surgical guiding bone plate.
- the fixed bone plate correction module can accurately position and correct the position of the bone for the fixed bone plate for providing postoperative bone healing.
- the facial surgery image correction design system wherein the surgical data parameter is a moving distance of a skeleton bone, a surgical cutting angle or a bone overlapping portion.
- the facial surgery image correction design system wherein the display device is a liquid crystal screen, a tablet computer, a PDA or a smart phone.
- FIG. 1 is a functional block diagram of a first embodiment of a cosmetic surgery image correction design system of the present invention.
- FIG. 2 is a functional block diagram of a second embodiment of a cosmetic surgery image correction design system of the present invention.
- FIG. 3 is a functional block diagram of a third embodiment of a cosmetic surgery image correction design system of the present invention.
- FIG. 4 is a functional block diagram of a fourth embodiment of a cosmetic surgery image correction design system of the present invention.
- FIG. 5 is a functional block diagram of a fifth embodiment of a cosmetic surgery image correction design system according to the present invention.
- FIG. 6 is a functional block diagram of a sixth embodiment of a cosmetic surgery image correction design system of the present invention.
- FIG. 7 is a flow chart of a first embodiment of a method for correcting image correction of a face-lift surgery according to the present invention.
- FIG. 8 is a flow chart of a second embodiment of a method for correcting image correction of a face-lift surgery according to the present invention.
- FIG. 9 is a flow chart of a third embodiment of a method for correcting image correction of a face-lift surgery according to the present invention.
- FIG. 10 is a flow chart of a fourth embodiment of a method for correcting image correction of a face-lift surgery according to the present invention.
- FIG. 11 is a flow chart of a fifth embodiment of a method for correcting image correction of a face-lift surgery according to the present invention.
- FIG. 12 is a flow chart of a sixth implementation of a method for correcting image correction of a face-lift surgery according to the present invention.
- FIG. 13 is a first scan image data of a cosmetic surgery image correction design system of the present invention.
- 15 is a scanning image correction comparison diagram of a cosmetic surgery image correction design system of the present invention.
- FIG. 16 is a diagram showing the image block operation layer management and the cutting block display diagram of the image correction design system of the face-lift surgery according to the present invention.
- 17 is a surgical simulation image of an input surgical parameter of a cosmetic surgery image correction design system of the present invention.
- FIG. 18 is a schematic view of a post-mortem image of a cosmetic surgery image correction design system of the present invention.
- FIG. 19 is a cross-sectional view of a surgical simulated image file and a bone plate correction for a cosmetic surgery image correction design system of the present invention.
- 20 is a display device for outputting a cosmetic surgery image correction design system of the present invention.
- a facial imaging image correction design system 1000 includes a first scanned image data module 1001, a first The second scan image data module 1002, a scan image correction comparison module 1003, an image block computing module 1004, a surgical analog image design module 1005, and an output module 1006.
- FIG. 2 is a functional block diagram showing a second embodiment of a cosmetic surgery image correction design system of the present invention Intention, when the doctor performs a correct operation for the patient, the X-ray machine or computed tomography CT diagnostic image file is required to confirm the expected operation site, and the one-spot surgery image correction design system 1000 can provide a correct and accurate image. The image is referenced by the physician. When the image processing design system 1000 is used, the first scanned image data module 1001 is opened, and the first scanned image data module 1001 is used for scanning to obtain the patient's face.
- the first scanned image data is a picture taken by the patient through an X-ray machine or a computed tomography device, such as a computed tomography file (hereinafter referred to as CT file), as shown in FIG. 1
- CT file computed tomography file
- the first scanned image data is shown in a computed tomography file (CT image file) and stored in the first scanned image data module 1001, and then continues to execute the second scanned image data module 1002.
- the second scanned image data module 1002 is for scanning image data of a patient's plaster dental mold, wherein the second scanned image data is as shown in FIG. 12 , wherein A patient's plaster dental mold is provided by the corrective dentist.
- the patient's preoperative occlusal dental model and the positive sacral simulation are performed as shown in Fig. 14(a), and then the patient's plaster teeth are scanned by a high precision grating instrument.
- the digital data of the obtained patient's teeth is the image file as shown in FIG. 14(b), and the image file is stored in the second scanned image data module 1002, wherein the image correction design of the facial surgery image is performed.
- the system 1000 further includes an image data conversion module 1012 for storing image data of the first scanned image data module 1001 (such as Dicom image data of the skull, soft tissue, and teeth) and a second scan.
- the image data of the image data module 1002 (such as the digital image data of the plaster dental mold) is used to further convert the first scanned image data and the second scanned image data into three dimensions by using the image data conversion module 1012 ( 3D) data file, wherein the three-dimensional (3D) data file format can be further transferred into a three-dimensional (3D) mechanical design STL file format for use in a computer 3D analog drawing and analysis.
- 3D image data conversion module 1012
- the image processing and correction system 1000 is executed to enable the image scanning comparison module 1003 to scan the image data of the first scanned image data set 1001 and the second scanned image data module.
- the image data of the group 1002 is input into the scanned image correction comparison module 1003 for image correction alignment, and the compared image files are archived, as shown in FIG. 15 is a scanning image correction of a cosmetic surgery image correction design system of the present invention.
- the comparison map as shown in Fig.
- Figure 15 (a) is a phantom image correction comparison image file
- Figure 15 (b) is the image data of the first scanned image data set 1001, which is the original CT file conversion
- Figure 15 (b) is the image data of the first scanned image data set 1001, which is the original CT file conversion
- the second scanned image data module 1002 to scan the obtained teeth of the patient's plaster dental mold by using a precision raster scanning instrument
- the tooth image data is converted by the three-dimensional (3D) data file
- the image data of the first scanned image data set 1001 (the 3D image file after the CT conversion) is performed by the scanned image correcting comparison module 1003.
- the stereoscopic position fitting and positioning is performed by replacing the tooth portion on the CT image file of the original first scanned image data with the actual size of the second scanned image data as shown in FIG. 15(c).
- the image processing module 1000 can be successively executed by an image block computing module 1004, and the image corrected by the scanned image correcting module 1003 is compared.
- Image archiving is shown in Figure 15(c).
- Surgery simulation layer management and cutting block display calculation are performed.
- a surgeon can use the above-mentioned Yan Yan surgery image correction design system 1000 to simulate a lower knife in a computer.
- Position, and according to the situation after the cutting in the simulated surgery, the parts are separated into layer management (as shown in Fig. 16), after the separation, the cut lower jaw is aligned to a correctional physician.
- the simulated occlusal position of the postoperative dental image is compared.
- the surgeon can perform a simulation comparison using the operation data of a surgical simulation image design module 1005 before performing the operation, and the above-mentioned image block operation is performed.
- the layer management performed by the module 1004 and the archiving block display operation are archived to input a surgical data parameter for designing a surgical simulation image file, such as a cutting part, a bone moving distance, and an opening angle. Or the relevant data of the overlap of the dental molds, etc., as shown in FIG.
- the computed surgical image file output using a surgical analog image design module 1005 is shown in Figure 20, at which point the surgical and orthodontist can discuss the position before and after the operation and simulate the postoperative situation.
- the display device 1006 is a liquid crystal screen, a tablet computer, a PDA, or a smart phone.
- FIG. 3 is a functional block diagram of a third embodiment of a cosmetic surgery image correction design system according to the present invention, wherein the image processing design system 1000 includes a first scanned image data module 1001.
- the image processing module 1000 is further included in the first scanned image data module 1001, and the image data conversion module 1010 is further configured to store the first scan.
- Image data of the image data module 1001 (such as CT image files for collecting skull, soft tissue and teeth) Dicom image data) is further converted into a three-dimensional (3D) data image file, wherein the three-dimensional (3D) data image format can be further transferred into a three-dimensional (3D) mechanical design STL file format for use in a computer 3D simulation drawing and analysis use, and then executing a scan image correction comparison module 1003, and the first scanned image data processed by the image data conversion module 1010 and the second scanned image data module 1002
- the image data is input into the scanned image correction comparison module 1003 for image correction alignment, and the compared image files are archived, and the second scanned image data is a three-dimensional (3D) data image file, and an image block is successively executed.
- the module functions such as the operation module 1004, the surgical analog image design module 1005, and the output module 1006 are
- FIG. 4 is a functional block diagram of a fourth embodiment of a cosmetic surgery image correction design system according to the present invention, wherein the image processing design system 1000 includes a first scanned image data module 1001.
- the image processing data of the first scanned image data set 1001 and the second image are performed by using a scan image correction comparison module 1003.
- the image data of the scanned image data module 1002 is input to the scanned image correction comparison module 1003 for image correction alignment and the compared image files are archived, wherein the image processed by the scanned image correction comparison module 1003 has
- the scanned image correction comparison module 1003 further includes a noise clearing module 1030 for noise in the archive, which may be caused by noise, other interference, and the like.
- the function of clearing and restoring the real image data, and performing the module function of the image block computing module 1004, the surgical analog image design module 1005, and the output module 1006 are implemented as in the above embodiment. Repeat the description.
- FIG. 5 is a functional block diagram of a fifth embodiment of a cosmetic surgery image correction design system according to the present invention, wherein the image processing design system 1000 includes a first scanned image data module 1001.
- the first scanned image data module 1001, the second scanned image data module 1002, a scanned image correction comparison module 1003, and an image block computing module 1004 are provided.
- the layer management performed by the image block computing module 1004 is performed.
- the cutting block displays an operation archive, and inputs a surgical data parameter for designing a surgical simulation image file, wherein the surgical parameter is related information such as a cutting part, a bone moving distance, an angle or a tooth mold overlapping part, wherein
- the surgical simulation image design module 1005 can further include a bone plate correction module 1050, wherein the operation data of the surgical simulation image design module 1005 can input the simulated image file of the surgical site into a 3D printing technology machine.
- the plate correction module 1050 performs calibration, and after the correction, the pre-operative cutting guide bone plate or the bone plate for fixing the bending plate is prepared in advance.
- the shape of the postoperative or the fixed bone plate device made by the 3D printing technique or the metal laser lamination technique to meet the postoperative combination, and the above-mentioned production related bone plate is bonded to the positioning hole and marked on the model, as shown in FIG.
- Figure 18 shows a post-operative sputum imaging simulation, which allows the physician to simulate the postoperative results and shorten the surgical time course, thereby improving the success rate of the above surgery.
- FIG. 6 is a functional block diagram of a sixth embodiment of a cosmetic surgery image correction design system according to the present invention.
- the bone plate correction module 1050 may further include a surgical guide bone plate correction module 1051 and A fixed bone plate correction module 1052, the above-mentioned surgical guide bone plate correction module 1051, provides surgical cutting area correction and surgical guiding bone plate accurate drilling alignment correction, the fixed bone plate correction module 1052 provides surgery The precise alignment of the posterior bone healing fixed bone plate and the predetermined positional correction of the bone, and the remaining embodiments are implemented as in the above-described embodiment 5, and thus will not be repeatedly described herein.
- FIG. 7 is a first embodiment flowchart of a method for correcting image correction of a face-lift surgery according to the present invention, and a method for correcting image correction of a face-lift surgery, wherein the performing step includes: inputting a first scanned image data step 100, wherein the first The scanned image data is obtained by scanning the patient's facial bones and the relative coordinate position image data of the teeth and the soft tissue.
- the first scanned image data is a computed tomography file (referred to as a CT file) or a three-dimensional data file
- the second step is Inputting a second scanned image data step 200, the second scanned image
- the image data is scanned image data of the patient's plaster dental mold
- the second scanned image data is a three-dimensional data image file
- the third step is a scan image correction comparison step 300
- the first scanned image data is
- the second scanned image data is compared and archived
- the fourth step is followed by an image block operation step 400, where the archive is subjected to layer management and cutting block display, and the layer management is in a simulated operation. After the cutting, the parts are separately illustrated.
- Step 500 inputting the archive displayed by the layer management and cutting block, and inputting a surgical data parameter, wherein the surgical data parameter is related data such as a cutting part, a bone moving distance, an angle or a tooth mold overlapping part, and the like.
- Designing a surgical simulation image file to be constructed; and the final step is an output step 600, using the surgical simulation image file to be transmitted using a display device
- the screen is a liquid crystal display device, a tablet computer, PDA, or smart phone.
- FIG. 8 is a second embodiment flowchart of a method for correcting image correction of a face-lift surgery according to the present invention, and a method for correcting image correction of a face-lift operation, wherein the execution step is similar to the operation flow of FIG. 7 described above, wherein the first scan image data is input.
- the file format is a three-dimensional (3D) mechanical design STL file for providing a subsequent step, and then performing a scan image correction comparison step 300, and correcting the first scanned image data and the second scanned image data.
- the simulated image design step 500 is performed by inputting an archive of the layer management and the cutting block display, and inputting a surgical data parameter, wherein the surgical data parameter is a cutting part, a bone moving distance, an angle or a tooth mold overlapping part, and the like.
- Data for designing a surgical simulation image file; and the final step is an output step 600.
- FIG. 9 is a third embodiment flowchart of a method for correcting image correction of a face-lift surgery according to the present invention, and a method for correcting image correction of a face-lift surgery, wherein the execution steps are similar to the operation flow of FIG. 7 described above, wherein
- the scanning image data step 100 further includes an image data conversion step 110, converting the first scanned image data into a three-dimensional (3D) data image file, and continuing to input the second scanned image data step 200, the second scanning The image data is used to scan the image data of the patient's plaster dental mold, and then perform a scan.
- the image correction is compared with the step 300, and the first scanned image data and the second scanned image data are compared and archived, and then the image block operation step 400 is performed to perform layer management and cutting on the archive.
- the block shows that the layer management separates the parts according to the situation after the cutting in the simulated operation, and the above separate illustration performs the comparison operation and cutting according to the occlusal position of the simulated dental model image provided by a correcting physician.
- the block displays and executes a surgical simulation image design step 500, and inputs the archived display and the archive displayed by the cutting block into a surgical data parameter, wherein the surgical data parameter is a cutting part, a bone moving distance, and an angle.
- the relevant information such as the overlap of the dental molds is used to design the surgical simulation image file; and the final step is an output step 600.
- the scan image correction comparison step 300 further includes a noise removal step 310, wherein the scan image correction ratio is performed.
- the image processed in step 300 may be caused by noise, other interference, and the like, so that the file that is transferred out is distorted or the picture is blurred. Therefore, the noise clearing step 310 is used to clear the archived noise, restore the real image data, and continue to perform the image.
- Block operation step 400 performing layer management and cutting block display on the archive, the layer management is to separate parts according to the situation after the simulated intraoperative cutting, the separate illustration is provided according to a correctional physician Simulate the occlusal position of the postoperative dental model image for comparison operation and cutting block display, and perform a surgical simulation
- the design step 500 the archive displayed by the layer management and the cutting block is input into a surgical data parameter, and the surgical data parameter is related information such as a cutting part, a bone moving distance, an angle or a tooth mold overlapping part, and the like.
- the design is used to design a surgical simulation image file; and the final step is an output step 600.
- FIG. 11 is a fifth embodiment flowchart of a method for correcting image correction of a face-lift surgery according to the present invention, and a method for correcting image correction of a face-lift surgery, wherein the execution step is similar to the operation flow of FIG. 7 described above, and the input first scan is performed.
- a bone plate correction step 510 may be further included.
- the surgical simulation image file is collated with the bone plate correction step 510.
- the bone plate is shaped to conform to the post-operative shape, and then made by 3D printing technology or metal laser lamination technology to meet the postoperative combined fixed bone plate device, and the above system
- the relevant bone plate is coupled to the positioning hole and marked on the model, and is adjusted according to the position and precision of the upper and lower occlusion position required by the surgeon to perform the intraoperative cutting and the postoperative correction of the need of the correcting dentist, and the image is archived.
- the operation of the simulated simulated image file using the surgical simulation image design step 500 and the bone plate correction step 510, the final step is an output step 600, which facilitates the surgical and corrective dentist's preoperative and postoperative accuracy test verification.
- the bone plate correcting step 510 includes a surgical guiding bone plate correcting step 511 and a fixed bone plate correcting step 512, the surgical guiding bone plate correcting step 511, providing surgery Cutting area correction and surgical guiding bone plate accurate drilling alignment correction, the above fixed bone plate correction step 512, providing surgery Bone plate fixing bone healing and bone can be precisely predetermined position on the correction position, as the remaining embodiments like state operation of the fifth embodiment in the flowchart of embodiments, it is not be repeated in this description.
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Abstract
Description
Claims (22)
- 一种颜颚手术影像校正设计方法,其步骤包括:输入第一扫描影像资料步骤,所述第一扫描影像资料为扫描取得颜颚骨骼及牙齿和软组织相对坐标位置的影像资料;再输入第二扫描影像资料步骤,所述第二扫描影像资料为扫描患者石膏牙模的影像资料;执行一扫描影像校正比对步骤,将所述第一扫描影像资料与所述第二扫描影像资料进行校正比对并存档;接续进行影像区块运算步骤,将所述存档进行图层管理及切割区块显示;执行一手术仿真影像设计步骤,将所述经图层管理及切割区块显示的存档,以输入执行一手术资料参数,用以设计手术仿真影像图档建置;以及一输出步骤,将所述手术仿真影像图档利用一显示设备输出。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中进一步包含一影像资料转换步骤,将所述第一扫描影像资料及第二扫描影像资料转换为三维资料图档。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中在输入第一扫描影像资料步骤之后进一步包含一影像资料转换步骤,将所述第一扫描影像资料转换为三维(3D)资料图档。
- 如权利要求2或3项所述的颜颚手术影像校正设计方法,其中所述三维资料图档格式为三维(3D)机械设计STL档案。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中所述第一扫描影像资料为电脑断层扫描文件(简称CT文件)。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中所述第二扫描影像资料为经一精密光栅机械扫描所述患者石膏牙模的影像资料。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中在所述扫描影像校正比对步骤之后进一步包含一噪声清除步骤,用以将所述存档噪声清除。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中进一步包含一骨板校正步骤,将所述手术仿真影像图档与所述骨板校正步骤进行核对。
- 如权利要求8所述的颜颚手术影像校正设计方法,其中所述骨板校正步骤包含一手术导引骨板校正步骤及一固定骨板校正步骤。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中所述手术资料参数为颜颚骨骼的移动距离、手术切割角度或骨骼重叠部位。
- 如权利要求1所述的颜颚手术影像校正设计方法,其中所述显示设备为液晶屏幕、平板电脑、PDA或智能手机。
- 一种颜颚手术影像校正设计系统,其包括:第一扫描影像资料模组,所述第一扫描影像资料模组为扫描取得颜颚骨骼及牙齿和软组织相对坐标位置影像资料;第二扫描影像资料模组,所述第二扫描影像资料模组为扫描患者石膏牙模的影像资料;一扫描影像校正比对模组,将所述第一扫描影像资料组的影像资料与所述第二扫描影像资料模组的影像资料进行校正比对并存档;一影像区块运算模组,将上述所述存档进行图层管理及切割区块显示;一手术仿真影像设计模组,将所述经图层管理及切割区块显示的存档,以输入一手术资料参数,用以设计手术仿真影像图档建置;以及一输出模组,将上述所述手术仿真影像图档以利用一显示设备输出。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中进一步包含一影像资料转换模组,将所述第一扫描影像资料模组的影像资料及第二扫描影像资料模组的影像资料转换为三维资料图档。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中第一扫描影像资料模组再进一步包含一影像资料转换模组,将所述第一扫描影像资料模组的影像资料转换为三维(3D)资料图档。
- 如权利要求12或13项所述的颜颚手术影像校正设计系统,其中所述三维数据图档格式为三维(3D)机械设计STL档案。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中所述第一扫描影像资料模组的影像资料为电脑断层扫描档(简称CT档)。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中所述第二扫描影像资料模组的影像资料为经一精密光栅机械扫描所述患者石膏牙模的影像资料。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中在所述扫描影像校正比对模组内进一步包含一噪声清除模组,用以将所述存档噪声清除。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中进一步包含一骨板校正模组,将所述手术仿真影像图档与所述骨板校正模组资料进行核对。
- 如权利要求19所述的颜颚手术影像校正设计系统,其中所述一骨板校正模块为包含一手术导引骨板校正模组及一固定骨板校正模组。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中所述手术资料参数为颜颚骨骼的移动距离、手术切割角度或骨骼重叠部位。
- 如权利要求11所述的颜颚手术影像校正设计系统,其中所述显示设备为液晶屏幕、平板电脑、PDA或智能手机。
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2020512067A (ja) * | 2017-03-07 | 2020-04-23 | メガジェン インプラント カンパニー リミテッドMegagen Implant Co., Ltd. | 3次元ハイブリッド映像構築プログラムを利用した顎矯正システム |
CN111938819A (zh) * | 2020-08-15 | 2020-11-17 | 山东大学齐鲁医院 | 一种脊柱外科微创手术导航系统 |
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US10376319B2 (en) | 2019-08-13 |
US20180147015A1 (en) | 2018-05-31 |
EP3308711A4 (en) | 2019-02-20 |
KR20180016406A (ko) | 2018-02-14 |
JP2018516708A (ja) | 2018-06-28 |
JP6578026B2 (ja) | 2019-09-18 |
EP3308711A1 (en) | 2018-04-18 |
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