Evaluation of autofluorescence visualization system in the delineation of oral squamous cell carcinoma surgical margins.

INTRODUCTION: Delineating the margins of Oral squamous cell carcinoma (OSCC) is a critical step for optimaltumor resection. The aim of this study was to evaluate the accuracy of lesion surgical margin identification using autofluorescence visualization. MATERIALS AND METHODS: Thirty patients with OSCC were included in this study. For each lesion, the fluorescence loss boundary was determined using VELscope before ablative surgical resection (with a 1.5-2cm safety margin) was performed. A total of 126 samples were obtained from 30 surgical specimens, each containing the tissue from the fluorescence loss boundary to surgical margin. The status of each sample was determined by oral pathologists and the staining intensities of Ki-67, E-cadherin, and Vimentin at the fluorescence loss boundary and surgical margin were evaluated by immunohistochemistry. RESULTS: Fluorescence loss regions were identified in all patients. Of the 126 samples collected, HE staining identified 77 normal epithelia (61.1%), 26 mild dysplasia (20.6%), 17 severe dysplasia (13.4%) and 6 carcinomas in situ (4.9%). A significant correlation was found between the differentiation grade of tumor cells and the pathological status of the surgical marginal specimens (P<0.05). Forty-two of the 126 samples were randomly selected for further immunohistochemical staining. No significant differences were seen in Ki-67, E-cadherin, or Vimentin expression at the fluorescence loss boundary or surgical margin, however, the proteins' expression level was positively correlated with the degree of dysplasia (P<0.01). CONCLUSION: Autofluorescence visualization has potential as a simple surgical margin setting device for OSCC and may help delineate the superficial area of OSCC with acceptable accuracy. However, when considering the inherent limitations of this system, we suggest that the approach should only be applied under certain conditions, such as when dealing with superficial, well-differentiated lesions.

MiR-34a inhibits the proliferation, migration, and invasion of oral squamous cell carcinoma by directly targeting SATB2.

In various kinds of carcinomas, the special AT-rich sequence-binding protein 2 (SATB2) with its atypical expression promotes the metastasis and progression of the tumor, though in the oral squamous cell carcinoma (OSCC) its inherent mechanism and the status of SATB2 remain unclear. The role played by the SATB2 expression in the OSCC cell lines and tissue samples in the target of miR-34a downstream is the intended endeavor of this study. In te OSCCs the miR-34a expression was determined by quantitative real-time polymerase chain reaction (q-PCR), while the SATB2 expression in the cell lines and tissue samples in OSCC was analyzed with the q-PCR and the western blot. Studies in both in vitro and in vivo of the effects of miR-34a on the initiation of OSCC were conducted. As a direct target of the miR-34a the SATB2 was verified with the luciferase reporter assay. In cases where the miR-34a levels were low, the SATB2 in OSCCs seemed to be overexpressed. Besides, both in the in vitro and in vivo a suppression of migration, invasion, and cell growth was caused by miR-34a by down regulating the SATB2 expression. The SATB2 being a direct target of miR-34a was confirmed by the cotransfection of miR-34a mimics specifically the decrease in the expression of luciferase of SATB2-3'UTR-wt reporter. As a whole, our study confirmed the inhibition of miR-34a in the invasion, proliferation, and migration of the OSCCs, playing a potential tumor suppressor role with SATB2 as its downstream target.

Computer-aided design-based preoperative planning of screw osteosynthesis for type B condylar head fractures: A preliminary study.

OBJECTIVE: To investigate the clinical application of a new computer-aided design - (CAD) based planning method for the treatment of type B condylar head fractures without fragmentation. METHODS: A total of 13 adult patients (19 sides) with type B condylar head fractures were included in the study. In all cases, imaging was performed using cone bean computed tomography (CBCT) preoperative, and Digital Imaging and Communications in Medicine (DICOM) files were imported into Simplant 11.04 software. The fracture of the mandibular condyle was reconstructed by a three-dimensional reconstruction module, and the simulation of reduction was achieved according to the morphological characteristics. Preoperative design was performed based on the CAD technology, and the three-dimensional interface was used to determine the length, location, and orientation of the positional screw. Osteosynthesis was performed with a single positional screw according to the optimum direction assessed in the preoperative planning CBCT, and the result was confirmed with postoperative CBCT scans and clinical follow-up. RESULTS: Preoperative computer-aided design was able to predict the length, location, and direction of the positional screw. Postoperative CBCT results demonstrated that 12 cases (18 sides) were consistent with preoperative design with exception of one case (one side) due to unexpected rupture of the fragment. Six-month follow-up showed the condylar fractures were anatomically repositioned and that healing was excellent in 12 cases (18 sides) with minor displacement and resorption in one case (one side). Postoperative occlusion in all cases was excellent, and the maximum mouth opening improved from mean 1.2 cm preoperatively to a of mean 4.3 cm at 6 months postoperatively. The data for mandibular movements at 6 months postoperatively demonstrated the recovery of protrusion, without higher grade limitations for laterotrusion. In one case, there appeared to be mandibular deviation (<0.5 cm) with mouth opening. CONCLUSION: The new preoperative design provides relevant data for screw osteosynthesis to enhance the precision and effectiveness of open reduction and internal fixation type B condylar head fractures.