ABSTRACT
Objective:To investigate the effects of 3D video thoracoscopic surgery combined with 3D CTBA (three-dimensional computed tomography bronchography and angiography) method in clinical education practice of the undergraduates.Methods:The study included in 60 undergraduate clinical interns from our hospital, and they were randomly divided into the experimental group ( n=30) and control group ( n=30). The teaching content was diagnosis and surgical treatment of lung cancer. The experimental group applied 3D video thoracoscopic surgery combined with 3D CTBA teaching method. The interns studied the anatomy of lung and diagnosis of lung cancer based on the 3DCTBA and visited the operation of lung cancer under 3D thoracoscopy, which enhanced their knowledge of anatomical structure of lung. The control group applied traditional thoracoscopic surgery for lung cancer. Upon termination of clinic practice, all interns were tested with theoretical and clinical knowledge of lung cancer. A questionnaire survey was conducted among them to access the teaching effect. SPSS 18.0 was used for t test and chi-square test. Results:The scores of theory test were not significantly different between two groups. The scores of anatomic and operational knowledge of lung in the experimental group were significantly higher compared with the control group ( P<0.05). Questionnaire result showed that new teaching method could promote the interest in learning, motivated the desire for thoracic surgery, and improved the comprehension of clinical knowledge. More students approved the new teaching method. Conclusion:The new method, 3D video thoracoscopic surgery combined with 3D CTBA, has beneficial effect on clinical interns, which contributes to inspire the motivation and interest of learning and deepen clinic knowledge, and is a promising teaching method worthy of further exploration and application.
ABSTRACT
@#More and more relevant research results show that anatomical segmentectomy has the same effect as traditional lobectomy in the surgical treatment of early-stage non-small cell lung cancer (diameter<2.0 cm). Segmentectomy is more difficult than lobotomy. Nowadays, with the promotion of personalization medicine and precision medicine, three-dimensional technique has been widely applied in the medical field. It has advantages such as preoperative simulation, intraoperative positioning, intraoperative navigation, clinical teaching and so on. It plays a key role in the discovery of local anatomical variation of pulmonary segment. This paper reviewed the clinical application of three-dimensional technique and briefly described the clinical application value of this technique in segmentectomy.
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BACKGROUND@#For early-stage lung cancer, segmentectomy can get the same oncological benefits as lobectomy. Accurate identification of the intersegmental border is the key to segmentectomy. This study used extended segmentectomy and extended subsegmentectomy to treat lung intersegmental and intersubsegmental ground-glass nodules (GGN) by utilizing modified inflation-deflation methods to distinguish the intersegmental and intersubsegmental borders. The accuracy of modified inflation-deflation methods and the effectiveness of extended resection to guarantee a safe surgical margin were evaluated.@*METHODS@#A retrospective analysis of 83 cases of extended segmentectomy and extended subsegmentectomy was conducted. Preoperative three-dimensional computed tomography bronchography and angiography (3D-CTBA) revealed that nodules were involved in intersegmental or intersubsegmental veins. Based on preoperative three-dimensional reconstruction, the surgery was designed to extendedly remove the dominant lung segment or subsegment with nodules involved. When the dominant lung segment or subsegment could not be identified, the simpler lung segment or subsegment was selected for the resection. After the target vessel and bronchus were cut off during the operation, modified inflation-deflation method was used to determine the border, and a stapler was used to resect the adjacent lung segment or subsegment tissue by 2 cm-3 cm around the inflation-deflation boundary line. Then, the relationship between the inflation-deflation boundary line and the nodule and the width of the surgical margin were measured. Clinical data were collected during the perioperative period.@*RESULTS@#56 extended segmentectomies and 27 extended subsegmentectomies were performed. The average diameter of pulmonary nodules was (0.9±0.3) cm. There were 79 cases with clearly inflation-deflation boundary lines. The average time needed for the appearance of the lines was (13.6±6.5) min. In 55 cases, the nodules were involved with the inflation-deflation boundary lines. Meanwhile, the remaining 24 cases revealed an average minimum distance of (0.6±0.3) cm between nodules and the boundary lines. The average width of surgical margin was (2.1±0.3) cm in these 79 cases. No deaths or major complications appeared during 30 d after operation.@*CONCLUSIONS@#The modified inflation-deflation method can effectively define the intersegmental and intersubsegmental borders, and guarantee the safe surgical margins of extended segmentectomy and extended subsegmentectomy to treat intersegmental and intersubsegmental small lung tumors.
ABSTRACT
@#Thoracoscopic pulmonary segmentectomy is one of the important treatment methods for early lung cancer. Only the premise of surgical precision can make the radical resection of lesions and maximum reservation of healthy lung tissue be simultaneously guaranteed. As a representative of the precise lung operation, the “cone-shaped lung segmentectomy” focuses on the lesion, and combines the anatomical characteristic of the patient to design individualized operation scheme. The technological core consists of three parts, three dimensional-computed tomography bronchography and angiography (3D-CTBA) surgery path planning, accurate definition of intersegmental demarcation and anatomic dissection of intersegmental borders along the demarcation. This paper aims to explore the technical process and quality control of the key techniques of thoracoscopic precise segmentectomy, so as to standardize the segmentectomy procedure under the principle of radical and minimally invasive therapy.