Development and validation of a robotic system for milling individualized jawbone cavities in oral and maxillofacial surgery.
Abstract
[OBJECTIVES] This study aimed to develop and validate a robotic system capable of performing accurate and minimally invasive jawbone milling procedures in oral and maxillofacial surgery.
[METHODS] The robotic hardware system mainly includes a UR5E arm (Universal Robots, Denmark) and the binocular positioning system (FusionTrack 250, Atracsys LLC, Switzerland). The robotic software (Dental Navi 3.0.0, Yakebot Technology Ltd., China) is capable of generating cutting tool paths based on three-dimensional shape description files, typically in the stereolithography format, and selected cutting tool parameters, as well as designing surgical accessories. Fully impacted supernumerary tooth models in the maxilla were fabricated using software and three-dimensional printing. Following the planning of a customized cavity to fully expose the tooth, maxillary bone milling was performed on both the robot and static guide groups (n = 8). After milling, all models underwent scanning for assessment.
[RESULTS] In the experiment with fully buried supernumerary tooth models in the maxilla, the root mean square, translation error, over-removal rate, and maximum distance were significantly smaller in the robot group compared to the static guide group. Moreover, the overlap ratio and Dice coefficient were significantly greater in the robot group. No statistically significant differences were observed between the two groups in terms of the rotation error (P = 0.80) or under-removal rate (P = 0.92).
[CONCLUSIONS] This study has developed a robotic system for milling individualized jawbone cavities in oral and maxillofacial surgery, and its accuracy has been preliminarily verified to meet clinical requirements.
[CLINICAL SIGNIFICANCE] The robotic system can achieve precise, minimally invasive, individualized jawbone milling in a variety of oral and maxillofacial surgeries, including tooth autotransplantation, surgical reshaping for zygomatic fibrous dysplasia, removal of fully impacted supernumerary or impacted teeth, and endodontic microsurgery, among other relevant clinical applications.
[METHODS] The robotic hardware system mainly includes a UR5E arm (Universal Robots, Denmark) and the binocular positioning system (FusionTrack 250, Atracsys LLC, Switzerland). The robotic software (Dental Navi 3.0.0, Yakebot Technology Ltd., China) is capable of generating cutting tool paths based on three-dimensional shape description files, typically in the stereolithography format, and selected cutting tool parameters, as well as designing surgical accessories. Fully impacted supernumerary tooth models in the maxilla were fabricated using software and three-dimensional printing. Following the planning of a customized cavity to fully expose the tooth, maxillary bone milling was performed on both the robot and static guide groups (n = 8). After milling, all models underwent scanning for assessment.
[RESULTS] In the experiment with fully buried supernumerary tooth models in the maxilla, the root mean square, translation error, over-removal rate, and maximum distance were significantly smaller in the robot group compared to the static guide group. Moreover, the overlap ratio and Dice coefficient were significantly greater in the robot group. No statistically significant differences were observed between the two groups in terms of the rotation error (P = 0.80) or under-removal rate (P = 0.92).
[CONCLUSIONS] This study has developed a robotic system for milling individualized jawbone cavities in oral and maxillofacial surgery, and its accuracy has been preliminarily verified to meet clinical requirements.
[CLINICAL SIGNIFICANCE] The robotic system can achieve precise, minimally invasive, individualized jawbone milling in a variety of oral and maxillofacial surgeries, including tooth autotransplantation, surgical reshaping for zygomatic fibrous dysplasia, removal of fully impacted supernumerary or impacted teeth, and endodontic microsurgery, among other relevant clinical applications.
추출된 의학 개체 (NER)
| 유형 | 영어 표현 | 한국어 / 풀이 | UMLS CUI | 출처 | 등장 |
|---|---|---|---|---|---|
| 해부 | jawbone
|
하악골 | dict | 4 | |
| 해부 | maxilla
|
상악골 | dict | 2 | |
| 시술 | microsurgery
|
미세수술 | dict | 1 | |
| 해부 | oral
|
scispacy | 1 | ||
| 해부 | maxillofacial
|
scispacy | 1 | ||
| 해부 | tooth
|
scispacy | 1 | ||
| 해부 | teeth
|
scispacy | 1 | ||
| 합병증 | zygomatic fibrous
|
scispacy | 1 | ||
| 약물 | [OBJECTIVES]
|
scispacy | 1 | ||
| 약물 | [CONCLUSIONS]
|
scispacy | 1 | ||
| 질환 | tooth
|
C0040426
Tooth structure
|
scispacy | 1 | |
| 질환 | tooth, maxillary bone milling
|
scispacy | 1 | ||
| 질환 | zygomatic fibrous dysplasia
|
scispacy | 1 | ||
| 질환 | LLC
|
scispacy | 1 | ||
| 기타 | jawbone cavities
|
scispacy | 1 | ||
| 기타 | FusionTrack
|
scispacy | 1 | ||
| 기타 | Navi
|
scispacy | 1 | ||
| 기타 | maxillary bone
|
scispacy | 1 |
MeSH Terms
Humans; Robotics; Printing, Three-Dimensional; Maxilla; Software; Tooth, Supernumerary; Minimally Invasive Surgical Procedures; Models, Dental; Surgery, Computer-Assisted; Models, Anatomic; Surgery, Oral; Computer-Aided Design; Stereolithography
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