Search Results (2)

Background: Two-dimensional periapical radiographs (PAs) only offer limited information regarding three-dimensional periodontal infrabony defects. In contrast, cone beam computed tomography (CBCT) enables visualization of the entire defect morphology. This study aimed to evaluate the agreement between CBCT and direct intrasurgical measurements (ISs) regarding the characteristics of infrabony defects, including measurements of defect depth, width, the type of defect (one-wall, two-wall, three-wall), and defect extension. Methods: Intrasurgical and radiographic assessments were performed by two calibrated examiners on 26 infrabony defects in 17 patients who underwent periodontal surgery. The defect depth, width, type, and extension were compared between intrasurgical observations and PA or CBCT findings. The CBCT assessment was performed mainly using axial reconstructions. Angle measurements were compared between CBCT and PAs. Results: The mean differences between CBCT and intrasurgical measurements were −0.11 ± 0.49 mm for depth and −0.07 ± 0.41 mm for width, with no significant differences. The ICC values were 0.938 and 0.923 for depth and width, respectively. The mean difference in width between PAs and ISs was significantly different (−0.36 ± 0.73 mm; p = 0.002). CBCT demonstrated high agreement with intrasurgical observations for defect type (κ = 0.819) and defect extension (κ = 0.855), while lower agreements were found for PAs. Conclusions: CBCT is a valid assessment modality for infrabony defects. It demonstrated strong agreement with ISs—as the gold standard—for depth and width measurements, and its agreement with ISs regarding defect type and extension appeared to surpass that of PAs. Full article

Mature adipocyte-derived dedifferentiated fat (DFAT) cells show proliferative capabilities and multipotency. Given that the buccal fat pad (BFP) serves as a readily available resource for DFAT cell isolation, BFP-derived DFAT (BFP-DFAT) cells are a promising candidate in orofacial tissue engineering. In this research, we assessed the regenerative capacity of the periodontium through autologous BFP-DFAT cell transplantation in adult swine (micro-minipigs; MMPs). The BFP-DFAT cells were transplanted into inflammation-inducing two-walled infrabony periodontal defects located on the mesial of the second mandibular premolar (n = 6). Twelve weeks post-transplantation, a remarkable attachment gain was noted in the DFAT group, based on probing depths and clinical attachment levels. Histological and immunohistochemical analyses indicated new continuous cellular cementum and alveolar bone formation within the created infrabony defect. Well-organized periodontal ligament-like fibers were embedded between newly formed cementum and the alveolar bone. Histometric analysis demonstrated that the DFAT group had a 2.2-fold increase in new alveolar bone length and a 2.2-fold enhancement in vascularization than those in the control group. Except for minor inflammation in the lungs, no teratomas were detected in the recipient MMPs. BFP-DFAT cells significantly enhanced periodontal tissue regeneration, thus representing an optimal source for tissue engineering applications in dentistry. Full article