RESUMO
OBJECTIVE: Primary nasal correction has been demonstrated to be a beneficial practice for patients with unilateral cleft lip and palate. However, there is currently no consensus among cleft surgeons regarding the ideal approach to addressing the malpositioned cartilages. This study aims to introduce a new surgical technique for repositioning deformed lower lateral cartilage during primary cleft rhinoplasty, which involves using a customized suture needle. DESIGN: Retrospective cohort study. SETTING: Tertiary university-affiliated hospital. PARTICIPANTS: This retrospective study included 51 patients with unilateral cleft lip and palate who underwent primary rhinoplasty during the labial repair. MAIN OUTCOME MEASURES: A morphological analysis of the nose was conducted using three-dimensional (3D) photographs. The cleft-to-noncleft side ratios of various nasal parameters, including nasal tip volume, nostril width, height, and area, were calculated at three time points: preoperative (T0), 3 months postoperative (T1), and 1 year postoperative (T2). RESULTS: Significant improvement (p < 0.05) was observed in the cleft-to-noncleft side ratios of nasal volume and nostril parameters. The nasal volume ratio and nostril height ratio remained stable, with no significant differences between the T1 and T2 periods. The nostril width ratio increased from 0.96 ± 0.13 at T1 to 1.05 ± 0.16 at T2, indicating an appropriate degree of surgical overcorrection of nasal width during primary lip repair. CONCLUSION: Primary cleft rhinoplasty using a Chang's needle allows direct suture placement in the intercartilaginous region with minimally invasive approach, thereby preserving growth potential of the nose and restoring the nasal symmetry.
RESUMO
(1) Background: In the present study, we evaluated the efficacy of a 3D-printed, patient-specific polycaprolactone/beta tricalcium phosphate (PCL/ß-TCP) scaffold in the treatment of complex zygomatico-maxillary defects. (2) Methods: We evaluated eight patients who underwent immediate or delayed maxillary reconstruction with patient-specific PCL implants between December 2019 and June 2021. The efficacy of these techniques was assessed using the volume and density analysis of computed tomography data obtained before surgery and six months after surgery. (3) Results: Patients underwent maxillary reconstruction with the 3D-printed PCL/ß-TCP scaffold based on various reconstructive techniques, including bone graft, fasciocutaneous free flaps, and fat graft. In the volume analysis, satisfactory volume conformity was achieved between the preoperative simulation and actual implant volume with a mean volume conformity of 79.71%, ranging from 70.89% to 86.31%. The ratio of de novo bone formation to total implant volume (bone volume fraction) was satisfactory with a mean bone fraction volume of 23.34%, ranging from 7.81% to 66.21%. Mean tissue density in the region of interest was 188.84 HU, ranging from 151.48 HU to 291.74 HU. (4) Conclusions: The combined use of the PCL/ß-TCP scaffold with virtual surgical simulation and 3D printing techniques may replace traditional non-absorbable implants in the future owing to its accuracy and biocompatible properties.