Long-term follow-up implant site development in the submerged mandibular primary second molars: a case report.

Treatment of ankylosed and submerged primary molars without permanent successors is challenging, as normal vertical dentoalveolar growth is compromised. Thus, grafting techniques and distraction osteogenesis are performed for ridge augmentation before implant restoration. However, these techniques are invasive with limited success. Another treatment for implant site development is noninvasive forced eruption. This case report describes long-term follow-up of alveolar ridge augmentation in the submerged mandibular primary second molars using subluxation and orthodontic forced eruption for implant site development. A 19-year old female had Class II molar relationships, upper anterior crowding with large overjet, missing four second premolars and submerged mandibular primary second molars with inadequate vertical development of alveolar bone. For the vertical alveolar bone alterations in the mandible, forced eruption with subluxation of ankylosed lower primary second molars was applied. Treatment outcome was evaluated over 5 years with stable occlusion, healthy periodontal tissues, and successful radiographic results.

Cone beam computed tomography (CBCT) for diagnosis and treatment planning in periodontology: systematic review update.

OBJECTIVES: To update the findings of a systematic review from the year 2016 on the evidence for the accuracy and potential benefits of cone beam computed tomography (CBCT) in periodontal diagnostics. MATERIAL AND METHODS: A systematic literature search was performed and the criteria for PICO, PRISMA and risk of bias assessment were applied. Only clinical trials (> 10 patients) conducted in humans on periodontal bone loss, i.e. vertical and/or horizontal or furcation involvement, in CBCT compared with clinical and/or conventional radiographic measures were included. RESULTS: From 1152 articles identified, 11 case series on furcations and eight on vertical and/or horizontal bone loss were included. The studies showed moderate risk of bias and heterogeneous study designs. The agreement between non-surgical clinical or two-dimensional radiographic assessments of horizontal, vertical or interfurcal bone loss and CBCT measurements was analysed in 11 studies and was low in six studies with comparable study designs. A high accuracy (80-84%) of CBCT measurements compared with intra-surgical findings of furcation involvement was observed in four studies. Comparing CBCT with intra-surgical measurements of vertical or horizontal bone loss, an accuracy between 58 and 93% was found in four out of six studies. Three studies were analysed and indicated benefits of CBCT in decision making and/or a reduction of treatment costs and time in teeth of interest. CONCLUSIONS: The findings provide additional evidence for the accuracy of CBCT in assessing periodontal bone loss. CLINICAL RELEVANCE: CBCT is an accurate diagnostic tool in periodontology, which needs to be carefully considered in certain situations.

Effect of DNA/protamine complex paste on bone augmentation of the mandible: A pilot study on dogs.

OBJECTIVE: Our previous studies found that a salmon DNA-based scaffold containing protamine promoted bone regeneration of the calvarial defects of rats. The aim of the present pilot study was to examine the influence of the DNA/protamine (DP) complex on bone regeneration of a saddle type, alveolar ridge defects of the dog mandible. DESIGN: Alveolar ridge defects were performed in the mandibles of five adult female beagles. The following three treatment modalities were randomly allocated: (1) the DP complex paste, (2) a beta-tricalcium phosphate (ß-TCP), and (3) a blank (control). Healing of bone defects were evaluated by periapical radiography, micro-computed tomography (micro-CT), and histology. RESULTS: Periodical radiographic images revealed that a higher percentage of regenerated bone height was consistently achieved in the DP group, as compared with blank controls. All three-dimensional, sagittal, and coronal images of micro-CT showed increased amounts of newly formed bone and a greater bone volume/ tissue volume ratio, as compared with the blank and ß-TCP groups. In contrast, there was no significant difference in bone mineral density among the groups. Histological analysis confirmed that the alveolar bone defects were filled with newly formed bone with mature and compact properties in the DP group. CONCLUSIONS: These findings indicate that the DP complexes enhanced regeneration of vertical alveolar bone defects of the dog mandible.

[Influence of three-wall osseous defects on periodontal ligament stress with three-dimensional finite element analysis].

OBJECTIVE: This study aims to explore the influence of three-wall osseous defects on periodontal ligament stress under normal occlusal forces. METHODS: A finite element model for mandibular total dentition, periodontal ligament and alveolar bone was created based on cone beam computed tomography (CBCT) DICOM images. Mesial or distal proximal three-wall osseous defects at varying depths (namely, 1/3, 2/3 and 3/3 of the root) were simulated by modifying the elastic modulus of elements within the defects area. Occlusal forces with an angle of 45° to the long axis of the tooth were applied to the finite element model. In addition, the equivalent stresses of the periodontal ligament were analysed. RESULTS: In the case of no bone defect, the mean value of the periodontal ligament equivalent stress of 14 teeth was 5.71 MPa. The equivalent stresses of the periodontal ligament at different depths (namely, 1/3, 2/3 and 3/3 of the root) were 6.61, 7.14 and 7.42 MPa, respectively. With increasing depth of the osseous defects, stress on the periodontal ligament increased considerably, and the initial stress increment was greater than that of a later stage. Periodontal ligament stresses with mesial proximal three-wall osseous defects (at depths of 1/3, 2/3 and 3/3 of the root) were 6.62, 7.19 and 7.51 MPa respectively. Periodontal ligament stresses with distal proximal three-wall osseous defects (at depths of 1/3, 2/3 and 3/3 of the root) were 6.60, 7.10 and 7.33 MPa, respectively. For three-wall osseous defects located in the mesial surface and distal surface, a significant difference in periodontal ligament stress was lacking. In the case of the same absorption depth, the size relationship of periodontal ligament stress was in the following order: premolars>molars>incisors>canines. CONCLUSIONS: Shallow three-wall osseous defects will likely cause a notable loss in strength of the periodontal ligament. Therefore, teeth with three-wall osseous defects should become the focus of clinical research. Treatment for these teeth should be administered as early as possible.

Influence of three-wall osseous defects on periodontal ligament stress with three-dimensional finite element analysis / 华西口腔医学杂志

OBJECTIVE@#This study aims to explore the influence of three-wall osseous defects on periodontal ligament stress under normal occlusal forces.@*METHODS@#A finite element model for mandibular total dentition, periodontal ligament and alveolar bone was created based on cone beam computed tomography (CBCT) DICOM images. Mesial or distal proximal three-wall osseous defects at varying depths (namely, 1/3, 2/3 and 3/3 of the root) were simulated by modifying the elastic modulus of elements within the defects area. Occlusal forces with an angle of 45° to the long axis of the tooth were applied to the finite element model. In addition, the equivalent stresses of the periodontal ligament were analysed.@*RESULTS@#In the case of no bone defect, the mean value of the periodontal ligament equivalent stress of 14 teeth was 5.71 MPa. The equivalent stresses of the periodontal ligament at different depths (namely, 1/3, 2/3 and 3/3 of the root) were 6.61, 7.14 and 7.42 MPa, respectively. With increasing depth of the osseous defects, stress on the periodontal ligament increased considerably, and the initial stress increment was greater than that of a later stage. Periodontal ligament stresses with mesial proximal three-wall osseous defects (at depths of 1/3, 2/3 and 3/3 of the root) were 6.62, 7.19 and 7.51 MPa respectively. Periodontal ligament stresses with distal proximal three-wall osseous defects (at depths of 1/3, 2/3 and 3/3 of the root) were 6.60, 7.10 and 7.33 MPa, respectively. For three-wall osseous defects located in the mesial surface and distal surface, a significant difference in periodontal ligament stress was lacking. In the case of the same absorption depth, the size relationship of periodontal ligament stress was in the following order: premolars>molars>incisors>canines.@*CONCLUSIONS@#Shallow three-wall osseous defects will likely cause a notable loss in strength of the periodontal ligament. Therefore, teeth with three-wall osseous defects should become the focus of clinical research. Treatment for these teeth should be administered as early as possible.