Search Results (4)

Background/Objectives: Computed tomography (CT)-guided transbronchial metallic coil marking is useful for identifying the locations of small peripheral pulmonary lesions. Even deeply located lesions may be accurately identified and resected with adequate margins. This method is also applicable to multiple lesions. The present study examined the efficacy of our marking method using cone-beam CT (CBCT) under general anesthesia in a hybrid operation room. Methods: In the hybrid operation room, an ultrathin bronchoscope was inserted into the objective bronchus under virtual bronchoscopic navigation, and a metallic coil was installed under CBCT guidance. The lesion was then resected with wedge resection by single- or 3-port video-assisted thoracoscopic surgery under fluorescence guidance. Eighty-seven patients with 90 lesions were treated between October 2016 and December 2022. The median lesion size was 11 mm and the median distance from the pleural surface was 8.7 mm. Lesions comprised 19 pure ground-glass nodule (GGN), 35 partly solid, and 36 solid types. Results: All lesions were visualized by CBCT, and metallic coils were installed into the objective bronchi. The median distance from lesions to coils was 3.6 mm, and the median marking time was 23.5 min. All lesions were resected with sufficient margins. In total, 57 lesions were diagnosed as primary lung cancer, 26 as metastatic lung tumors, 3 as nodular lymphoid hyperplasia, and 4 as others. There were no complications associated with the marking procedure. Conclusions: CBCT represents an alternative modality for identifying peripheral lung lesions due to its ability to visualize even small GGNs. It is a minimally invasive technique because the treatment sequence is completed under general anesthesia with the same quality as previous methods performed in a CT-equipped interventional radiology suite. Full article

Indocyanine green (ICG) fluorescence imaging has revolutionized surgical practice across various medical and surgical specialties. This article reviews the clinical applications of ICG in abdominal, urological, thoracic, and gynecological surgery. ICG fluorescence imaging has been widely adopted in general surgery for various applications, including perfusion assessment, intraoperative visualization of the ureter, and tumor localization. It is particularly valuable in evaluating anastomotic leaks and aiding in precise tumor resection during minimally invasive surgeries. Studies have shown mixed results on its effectiveness in reducing anastomotic leak rates, highlighting the need for further research. In thoracic surgery, ICG facilitates the identification and resection of pulmonary bullae, as well as the precise localization of pulmonary nodules during video-assisted surgery. In urology, ICG aids in localizing renal tumors and guiding selective arterial occlusion during partial nephrectomy. Its role in identifying the lymphatic pathway in prostate cancer and sentinel lymph node biopsy in gynecological cancer is also discussed. Despite its benefits, the use of ICG fluorescence faces challenges such as limited tissue penetration, the potential for false results, a lack of standardized protocols, and high equipment costs. Nonetheless, it remains a powerful tool that could improve surgical outcomes. Full article

Radiologic reconstruction technology allows the wide use of three-dimensional (3D) computed tomography (CT) images in thoracic surgery. A minimally invasive surgery has become one of the standard therapies in thoracic surgery, and therefore, the need for preoperative and intraoperative simulations has increased. Three-dimensional CT images have been extensively used, and various types of software have been developed to reconstruct 3D-CT images for surgical simulation worldwide. Several software types have been commercialized and widely used by not only radiologists and technicians, but also thoracic surgeons. Three-dimensional CT images are helpful surgical guides; however, in almost all cases, they provide only static images, different from the intraoperative views. Lungs are soft and variable organs that can easily change shape by intraoperative inflation/deflation and surgical procedures. To address this issue, we have developed a novel software called the Resection Process Map (RPM), which creates variable virtual 3D images. Herein, we introduce the RPM and its development by tracking the history of 3D CT imaging in thoracic surgery. The RPM could help develop a real-time and accurate surgical navigation system for thoracic surgery. Full article

Objective. To evaluate efficacy of diagnostic procedures, results of surgery, and complications in malignant pleural diseases.
Material and methods. From 1999 to 2006, 169 patients underwent treatment in the Department of Thoracic Surgery and Oncology, Institute of Oncology, Vilnius University. Patients were divided into two groups: group I, patients with primary pleural malignant diseases (93 patients, 55.0%), and group II, secondary pleural tumors (76 patients, 45%). Of the 76 patients, 40 patients (52.6%) were diagnosed with metastatic pleural tumors and 36 patients (47.4%) with tumors invading parietal pleura. We used noninvasive and invasive methods for diagnosis. Noninvasive methods included chest x-ray, chest computed tomography, magnetic resonance imaging, chest ultrasound, positron emission tomography/ computed tomography (performed in Germany), and invasive methods included puncture of pleural effusions, transthoracic pleural puncture, drainage, pleural biopsy and video-assisted thoracoscopic pleural biopsy, pleural resection, and ultrasound-guided needle biopsy of the pleura. The following procedures were performed in group I: pleurectomy in 15 patients (16.1%), pleural pneumonectomy in 42 patients (45.2%), pleural decortication in 12 patients (12.9%), extended pleuropneumonectomy with diaphragm and pericardium resections and plastic surgery in 14 patients (15.0%), pleurectomy with costal resections in 10 patients (10.1%). Procedures performed in group II included video-assisted thoracoscopic pleurectomy in 15 patients (19.7%), pleural biopsy in 10 patients (13.2%), pleurectomy in 15 patients (19.7%), pleural drainage and fenestration in 5 patients (6.5%), lung and pleura resection in 12 patients (15.8%), chest wall and pleura resection in 10 patients (13.2%), diaphragm and pleura resections in 9 patients (11.8%).
Results. Early stage primary pleural tumors were found in 24 patients (25.8%). Metastatic pleural disease was found in 32 patients with early primary tumors (80.0%). In all 36 patients (100.0%) with chest wall tumors, disease of advanced stage was determined. Main surgical complications of the group I were observed in 26 patients (27.9%). Six patients (6.5%) died after surgery. In group II, 23 patients (30.2%) had postoperative complications; 3 patients (3.9%) died.
Conclusions. In noninvasive methods, the highest sensitivity was achieved for chest computed tomography and magnetic resonance imaging (97%); the specificity of chest magnetic resonance imaging was 100%, and the specificity chest computed tomography and magnetic resonance imaging – 98%. The accuracy of chest xray plus computed tomography was 98%. In invasive methods, accuracies of pleural biopsy, video-assisted thoracoscopic pleural biopsy, and pleurectomy were 100%, 90%, and 100%, respectively. In case of primary pleural tumors, the main surgery was extended pleuropulmonectomy (45.2%) with or without mediastinal resection. Mortality rate was 6.5%. In case of metastatic pleural disease, the main surgery was video-assisted thoracoscopic pleurectomy (19.7%). Mortality was rate 5%. In cases of pleural invasion by other thoracic malignancies, the main surgeries were chest wall and pleural resection (13.2%) and lung and pleural resection (15.8%). Mortality rate was 2.8%. After 169 operati Full article