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Model Repositioning Instrument를 이용한 악교정 수술의 치험례
이남기,최동순,차봉근,박영욱,김지혁,Lee, Nam-Ki,Choi, Dong-Soon,Cha, Bong-Kuen,Park, Young-Wook,Kim, Ji-Hyuck 대한악안면성형재건외과학회 2006 Maxillofacial Plastic Reconstructive Surgery Vol.28 No.3
Moderate to severe dentofacial deformities usually require combined orthodontic treatment and orthognathic surgery to obtain the most stable result with optimal function and facial esthetics. Accordingly, the orthodontist and oral maxillofacial surgeon must be able to exactly diagnose existing deformities, establish an appropriate treatment plan, and execute the recommended treatment. Especially, to obtain optimal result of the maxillary surgery, model surgery is essential. But, the preoperatively planned position of the maxillary dental arch often cannot be sufficiently achieved during actual surgery, and deviations in the sagittal and vertical dimensions are common. To achieve three dimensional repositioning of the maxilla exactly, several methods have been introduced so far. Recently Model Repositioning Instrument (MRI, SAM, Inc., $M\ddot{u}nchen$, Germany), one of these methods, has been introduced and applied clinically, which is reported as accurate, effective and prompt method for three dimensional repositioning of the maxilla. This article describes an introduction and a clinical application of this MRI.
A study on the prevalence of the idiopathic osteosclerosis in Korean malocclusion patients
이승엽,박인우,장인산,최동순,차봉근,Lee, Seung-Youp,Park, In-Woo,Jang, In-San,Choi, Dong-Soon,Cha, Bong-Kuen Korean Academy of Oral and Maxillofacial Radiology 2010 Imaging Science in Dentistry Vol.40 No.4
Purpose : This retrospective study was performed to investigate the prevalence of the idiopathic osteosclerosis (IO) in Korean malocclusion patients according to age, sex, and the Angle's classification of malocclusion. Materials and Methods : This study consisted of 2,001 randomly selected patients from the Department of Orthodontics at the Gangneung-Wonju National University Dental Hospital, Korea. The prevalence of IO in Korean malocclusion patients was recorded using their panoramic radiographs, and the following parameters were surveyed; age, sex, and the Angle's classification of malocclusion. The chi-square test was analyzed to determine the statistical significance of differences in the prevalence of IO between age, sex, and the Angle's classification of malocclusion. Results : The prevalence of IO in the jaws was 6.7% in a total of 2,001 examined orthodontic patients. The majority of IO was found in the mandible (96.58%). The 30-39 age group showed the highest prevalence of IO (9.60%). There was a higher prevalence in females (6.89%) than in males (6.45%). The prevalence of IO in Angle Class I group (7.07%) was the most frequent, followed by Angle Class II group (6.72%), and Angle Class III group (6.40%). However, there was no statistical significance in sex and Angle's classification of malocclusion. Conclusion : The prevalence of IO in malocclusion patients showed the differences between various age groups and most of them were found in the mandibular posterior area. However, sex and the type of malocclusion are not to be considered as a contributing factor of IO.
악정형력 적용을 위한 골내 고정원으로서 미니플레이트 형상의 영향: 3차원 유한요소법적 연구
이남기,백승학,최동순,박영욱,김지혁,차봉근,Lee, Nam-Ki,Baek, Seung-Hak,Choi, Dong-Soon,Park, Young-Wook,Kim, Ji-Hyuck,Cha, Bong-Kuen 대한악안면성형재건외과학회 2008 Maxillofacial Plastic Reconstructive Surgery Vol.30 No.4
Purpose: This study was performed to evaluate the stress distribution in the bone and the displacement distribution of the miniscrew under orthopedic force with two different types of miniplate design as skeletal anchorage for orthopedic treatment. Materials and methods: Finite element models were made for 6-hole miniplate (0.8mm in thickness), which were designed in two different shapes-one is curvilinear shaped (C plate, Jeil Medical Co., Korea) and another, Y shaped (Y plate), fixed with 3 pieces of miniscrew 2mm-diameter and 6mm-long respectively. A traction force of 4 N was applied in $0^{\circ}$, $30^{\circ}$ and $60^{\circ}$ to imaginary axis connecting two unfixed distalmost holes of the miniplate. Results: The maximum von Mises stress in the bone was much greater in the cortical portion rather than in the cancellous portion. C plate showed greater maximum von Mises stress in the cortical bone than Y plate. The maximum displacement of the miniscrew was greater in C plate than Y plate. The more increased the angle of the applied orthopedic force, the greater maximum von Mises stress in the bone and maximum displacement of the miniscrew. It was observed that in C plate, the von Mises stress in the bone and displacement of the miniscrew were distributed around the distalmost screw-fixed area. Conclusions: The results suggest that Y plate should have the advantage over C plate and in the placement of the miniplate, its imaginary axis should be placed as parallel as possible to the direction of orthopedic force to obtain its primary stability.
3차원 얼굴 영상을 이용한 상악 전방견인 치료 후의 연조직 평가
최동순(Dong-Soon Choi),이경훈(Kyoung-Hoon Lee),장인산(Insan Jang),차봉근(Bong-Kuen Cha) 대한치과의사협회 2016 대한치과의사협회지 Vol.54 No.3
Purpose: The aim of this study was to evaluate the soft-tissue change after the maxillary protraction therapy using threedimensional (3D) facial images. Materials and Methods: This study used pretreatment (T1) and posttreatment (T2) 3D facial images from thirteen Class III malocclusion patients (6 boys and 7 girls; mean age, 8.9 2.2 years) who received maxillary protraction therapy. The facial images were taken using the optical scanner (Rexcan III 3D scanner), and T1 and T2 images were superimposed using forehead area as a reference. The soft-tissue changes after the treatment (T2-T1) were three-dimensionally calculated using 15 soft-tissue landmarks and 3 reference planes. Results: Anterior movements of the soft-tissue were observed on the pronasale, subnasale, nasal ala, soft-tissue zygoma, and upper lip area. Posterior movements were observed on the lower lip, soft-tissue B-point, and soft-tissue gnathion area. Vertically, most soft-tissue landmarks moved downward at T2. In transverse direction, bilateral landmarks, i.e. exocanthion, zygomatic point, nasal ala, and cheilion moved more laterally at T2. Conclusion: Facial soft-tissue of Class III malocclusion patients was changed three-dimensionally after maxillary protraction therapy. Especially, the facial profile was improved by forward movement of midface and downward and backward movement of lower face.