The objectives of this study were to compare the survival time of the Hawley retainer (HR) and the clear overlay retainer (COR) over one-year follow-up and to analyze risk factors contributing to their breakage. In this randomized, controlled clinical trial, we assigned 120 adolescent patients to receive either the HR or the COR. All specific data on breakage dates, the reasons for breakage, and the broken parts of the retainers were recorded. A survival analysis was used to describe retainer survival over time. No significant differences were observed in survival times between the 2 groups for either the maxillary retainer (p = 0.254) or the mandibular retainer (p = 0.188). Both retainers tended to fracture, but the fracture locations were different. The findings indicate that clinicians should avoid increasing buccal root torque and reinforce the retainer base plates. Breakage rates may not influence the choice of retainer (Trial Registration number is ChiCTR-TRC-00000055).
In this study, the effects of a chitosan bioelectret membrane on bone regeneration in a rabbit cranial defect model were examined. The bioelectret was fabricated by film casting and polarized by grid-controlled corona charging (−1 kV). In vitro, the equivalence surface charge density of the bioelectret gradually reduced under both wet and dry conditions. In vivo, two rectangular transosseous defects of 8 mm × 10 mm were created symmetrically on each rabbit cranial bone. The defects were treated with the bioelectret membrane, with unpolarized membrane, and no membrane, respectively. The rabbits were killed at 4, 8, and 12 weeks postoperatively, and specimens were examined by micro-computed tomography and histological analysis. The bioelectret membrane recipients had a significantly higher volume of newly formed bone and greater rate of material degradation than the unpolarized membrane. Furthermore, the bioelectret membrane induced new bone formation not only around the host bone but also in the center of the defects. The chitosan bioelectret membrane application has an apparent potential in guided bone regeneration applications.
Chitosan/nano-hydroxyapatite membranes with negative charges were fabricated by grid-controlled constant voltage corona charging, and the charged membranes were investigated for cell biocompatibility and osteoinduction. The osteoblasts on the chitosan/nano-hydroxyapatite composite electret membranes significantly enhanced the adhesion, proliferation, and differentiation capacity compared to the uncharged group. This study not only provides evidence for the potential clinical application of our novel membranes but also could be used as a strategy for chitosan/nano-hydroxyapatite scaffolds.
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